MVTX2603 Integrated 10/100/1000 Mbps Ethernet Switch Data Sheet DS5764 Issue 7 October 2002 Features • • • • • • Integrated Single-Chip 10/100/1000 Mbps Ethernet Switch 24 10/100 Mbps Autosensing, Fast Ethernet Ports with RMII or Serial Interface (7WS) 2 Gigabit Ports with GMII, PCS, 10/100 and stacking (2G per port) interface options per port Serial interface for configuration Supports two Frame Buffer Memory domains with SRAM at 100 MHz Supports memory size 2 MB, or 4 MB • For 24+2, two SRAM domains (2 MB or 4 MB) are required. • For 24+2 stacking (2G per stacking port), two ZBT domains (2 MB or 4 MB) are required. MVTX2603AG 553 Pin BGA -40°C to +85°C • • • • • • Supports per-system option to enable flow control for best effort frames even on QoS-enabled ports Load sharing among trunked ports can be based on source MAC and/or destination MAC. The Gigabit trunking group has one more option, based on source port. Port Mirroring to a dedicated port or port 23 Built-in reset logic triggered by system malfunction I2C EEPROM for configuration Traffic Classification • 4 transmission priorities for Fast Ethernet ports with 2 dropping levels • Classification based on: - Port based priority - VLAN Priority field in VLAN tagged frame - DS/TOS field in IP packet - UDP/TCP logical ports: 8 hard-wired and 8 VLAN 1 MCT • • • Applies centralized shared memory architecture Up to 64K MAC addresses Maximum throughput is 6.4 Gbps non-blocking High performance packet forwarding (9.524M packets per second) at full wire speed Full Duplex Ethernet IEEE 802.3x Flow Control Backpressure flow control for Half Duplex ports Supports Ethernet multicasting and broadcasting and flooding control VLAN 1 MCT • • • • Ordering Information Frame Data Buffer A SRAM (1M / 2M) Frame Data Buffer B SRAM (1M / 2M) FDB Interface FCB Frame Engine 24 x 10 /100 RMII Ports 0 - 23 GMII/ PCS Port 24 GMII/ PCS Port 25 LED Search Engine Management Module MCT Link Parallel/ Serial Figure 1 - MVTX2603AG System Block Diagram 1 MVTX2603 Data Sheet programmable ports, including one programmable range • The precedence of the above classifications is programmable. • QoS Support • Supports IEEE 802.1p/Q Quality of Service with 4 transmission priority queues with delay bounded, strict priority, and WFQ service disciplines • Provides 2 levels of dropping precedence with WRED mechanism • User controls the WRED thresholds. • Buffer management: per class and per port buffer reservations • Port-based priority: VLAN priority in a tagged frame can be overwritten by the priority of Port VLAN ID. • • • • • 3 port trunking groups, one for the 2 Gigabit ports, and two groups for 10/100 ports, with up to 4 10/100 ports per group Full set of LED signals provided by a serial interface, or 6 LED signals dedicated to Gigabit port status only (without serial interface) Hardware auto-negotiation through serial management interface (MDIO) for Ethernet ports Hardware auto-negotiation through serial management interface (MDIO) for Ethernet ports Built-In Self Test for internal and external SRAM Description The MVTX2603AG is a high density, low cost, high performance, non-blocking Ethernet switch chip. A single chip provides 24 ports at 10/100 Mbps, 2 ports at 1000 Mbps. The Gigabit ports can also support 10/100M and 2G stacking modes. The chip supports up to 64K MAC addresses. The centralized shared memory architecture permits a very high performance packet forwarding rate at up to 9.524M packets per second at full wire speed. The chip is optimized to provide low-cost, high-performance workgroup switching. Two Frame Buffer Memory domains utilize cost-effective, high-performance synchronous SRAM with aggregate bandwidth of 12.8 Gbps to support full wire speed on all ports simultaneously. In the 24+2 stacking (2G per stacking port) configuration, 2 ZBT domains are needed. With delay bounded, strict priority, and/or WFQ transmission scheduling, and WRED dropping schemes, the MVTX2603AG provides powerful QoS functions for various multimedia and mission-critical applications. The chip provides 4 transmission priorities (8 priorities per Gigabit port) and 2 levels of dropping precedence. Each packet is assigned a transmission priority and dropping precedence based on the VLAN priority field in a VLAN tagged frame, or the DS/TOS field, or the UDP/TCP logical port fields in IP packets. The MVTX2603AG recognizes a total of 16 UDP/TCP logical ports, 8 hard-wired and 8 programmable (including one programmable range). The MVTX2603AG supports 3 groups of port trunking/load sharing. One group is dedicated to the two Gigabit ports, and the other two groups to 10/100 ports, where each 10/100 group can contain up to 4 ports. Port trunking/load sharing can be used to group ports between interlinked switches to increase the effective network bandwidth. In half-duplex mode, all ports support backpressure flow control, to minimize the risk of losing data during long activity bursts. In full-duplex mode, IEEE 802.3x flow control is provided. The MVTX2603AG also supports a per-system option to enable flow control for best effort frames, even on QoS-enabled ports. The Physical Coding Sublayer (PCS) is integrated on-chip to provide a direct 10-bit interface for connection to SERDES chips. The PCS can be bypassed to provide a GMII interface. The MVTX2603AG is fabricated using 0.25 micron technology. Inputs, however, are 3.3 V tolerant, and the outputs are capable of directly interfacing to LVTTL levels. The MVTX2603AG is packaged in a 553-pin Ball Grid Array package. 2 Zarlink Semiconductor Inc. MVTX2603 Data Sheet Table of Contents Features ...................................................................................................................................1 Description ...............................................................................................................................2 1.0 Block Functionality ..........................................................................................................11 1.1 Frame Data Buffer (FDB) Interfaces.......................................................................................................... 11 1.2 GMII/PCS MAC Module (GMAC) .............................................................................................................. 11 1.3 Physical Coding Sublayer (PCI) Interface ................................................................................................. 11 1.4 10/100 MAC Module (RMAC).................................................................................................................... 11 1.5 Configuration Interface Module ................................................................................................................. 12 1.6 Frame Engine ............................................................................................................................................ 12 1.7 Search Engine ........................................................................................................................................... 12 1.8 LED Interface............................................................................................................................................. 12 1.9 Internal Memory......................................................................................................................................... 12 2.0 System Configuration ......................................................................................................12 2.1 Configuration Mode ................................................................................................................................... 12 2.2 I2C Interface .............................................................................................................................................. 12 2.2.1 Start Condition ................................................................................................................................. 12 2.2.2 Address ............................................................................................................................................ 13 2.2.3 Data Direction .................................................................................................................................. 13 2.2.4 Acknowledgment.............................................................................................................................. 13 2.2.5 Data.................................................................................................................................................. 13 2.2.6 Stop Condition.................................................................................................................................. 13 2.3 Synchronous Serial Interface .................................................................................................................... 13 2.3.1 Write Command ............................................................................................................................... 14 2.3.2 Read Command ............................................................................................................................... 14 2.4 Stacking..................................................................................................................................................... 14 3.0 MVTX2603AG Data Forwarding Protocol .......................................................................14 3.1 Unicast Data Frame Forwarding................................................................................................................ 14 3.2 Multicast Data Frame Forwarding ............................................................................................................. 15 4.0 Memory Interface..............................................................................................................16 4.1 Overview.................................................................................................................................................... 16 4.2 ZBT Support .............................................................................................................................................. 16 4.3 Detailed Memory Information .................................................................................................................... 16 4.4 Memory Requirements .............................................................................................................................. 17 5.0 Search Engine ..................................................................................................................17 5.1 Search Engine Overview ........................................................................................................................... 17 5.2 Basic Flow ................................................................................................................................................. 17 5.3 Search, Learning, and Aging ..................................................................................................................... 18 5.3.1 MAC Search..................................................................................................................................... 18 5.3.2 Learning ........................................................................................................................................... 18 5.3.3 Aging ................................................................................................................................................ 18 5.4 Quality of Service ...................................................................................................................................... 18 5.5 Priority Classification Rule......................................................................................................................... 19 5.6 Port Based VLAN ...................................................................................................................................... 20 5.7 Memory Configurations ............................................................................................................................. 20 6.0 Frame Engine....................................................................................................................24 6.1 Data Forwarding Summary........................................................................................................................ 24 6.2 Frame Engine Details ................................................................................................................................ 24 6.2.1 FCB Manager................................................................................................................................... 24 6.2.2 Rx Interface...................................................................................................................................... 24 6.2.3 RxDMA............................................................................................................................................. 24 Zarlink Semiconductor Inc. 3 MVTX2603 Data Sheet Table of Contents 6.2.4 TxQ Manager ...................................................................................................................................24 6.3 Port Control................................................................................................................................................25 6.4 TxDMA .......................................................................................................................................................25 7.0 Quality of Service and Flow Control .............................................................................. 25 7.1 Model .........................................................................................................................................................25 7.2 Four QoS Configurations ...........................................................................................................................26 7.3 Delay Bound ..............................................................................................................................................27 7.4 Strict Priority and Best Effort......................................................................................................................27 7.5 Weighted Fair Queuing ..............................................................................................................................28 7.6 Shaper .......................................................................................................................................................28 7.7 WRED Drop Threshold Management Support...........................................................................................29 7.8 Buffer Management ...................................................................................................................................29 7.8.1 Dropping When Buffers Are Scarce .................................................................................................30 7.9 MVTX2603AG Flow Control Basics ...........................................................................................................31 7.9.1 Unicast Flow Control ........................................................................................................................31 7.9.2 Multicast Flow Control ......................................................................................................................31 7.10 Mapping to IETF Diffserv Classes ...........................................................................................................32 8.0 Port Trunking ................................................................................................................... 33 8.1 Features and Restrictions ..........................................................................................................................33 8.2 Unicast Packet Forwarding ........................................................................................................................33 8.3 Multicast Packet Forwarding......................................................................................................................33 8.4 Trunking .....................................................................................................................................................34 9.0 Port Mirroring................................................................................................................... 34 9.1 Port Mirroring Features ..............................................................................................................................34 9.2 Setting Registers for Port Mirroring............................................................................................................34 10.0 TBI Interface ................................................................................................................... 35 11.0 GPSI (7WS) Interface ..................................................................................................... 36 11.1 11.1GPSI Connection ..............................................................................................................................36 11.2 SCAN LINK and SCAN COL interface.....................................................................................................37 12.0 LED Interface.................................................................................................................. 37 12.1 LED Interface Introduction .......................................................................................................................37 12.2 Port Status ...............................................................................................................................................37 12.3 LED Interface Timing Diagram.................................................................................................................38 13.0 Register Definition......................................................................................................... 39 13.1 MVTX2603AG Register Description ........................................................................................................39 13.2 Group 0 Address MAC Ports Group ........................................................................................................43 13.2.1 ECR1Pn: Port N Control Register ..................................................................................................43 13.2.2 ECR2Pn: Port N Control Register ..................................................................................................44 13.2.3 GGControl – Extra GIGA Port Control............................................................................................45 13.3 Group 1 Address VLAN Group ................................................................................................................46 13.3.1 AVTCL – VLAN Type Code Register Low......................................................................................46 13.3.2 AVTCH – VLAN Type Code Register High ....................................................................................46 13.3.3 PVMAP00_0 – Port 00 Configuration Register 0 ...........................................................................46 13.3.4 PVMAP00_1 – Port 00 Configuration Register 1 ...........................................................................46 13.3.5 PVMAP00_2 – Port 00 Configuration Register 2 ...........................................................................46 13.3.6 PVMAP00_3 – Port 00 Configuration Register 3 ...........................................................................47 13.4 Port Configuration Register......................................................................................................................47 13.4.1 PVMODE........................................................................................................................................48 13.4.2 TRUNK0_MODE– Trunk group 0 mode.........................................................................................48 4 Zarlink Semiconductor Inc. MVTX2603 Data Sheet Table of Contents 13.4.3 TRUNK1_MODE – Trunk group 1 mode........................................................................................ 49 13.4.4 TRUNK1_HASH0 – Trunk group 1 hash result 0 destination port number .................................... 49 13.4.5 TX_AGE – Tx Queue Aging timer .................................................................................................. 49 13.5 Group 4 Address Search Engine Group.................................................................................................. 49 13.5.1 AGETIME_LOW – MAC address aging time Low.......................................................................... 49 13.5.2 AGETIME_HIGH –MAC address aging time High ......................................................................... 50 13.5.3 V_AGETIME – VLAN to Port aging time ........................................................................................ 51 13.5.4 SE_OPMODE – Search Engine Operation Mode .......................................................................... 51 13.6 Group 5 Address Buffer Control/QOS Group .......................................................................................... 51 13.6.1 FCBAT – FCB Aging Timer............................................................................................................ 51 13.6.2 QOSC – QOS Control .................................................................................................................... 51 13.6.3 FCR – Flooding Control Register ................................................................................................... 52 13.6.4 AVPML – VLAN Priority Map ......................................................................................................... 53 13.6.5 AVPMM – VLAN Priority Map ........................................................................................................ 53 13.6.6 AVPMH – VLAN Priority Map......................................................................................................... 53 13.6.7 TOSPML – TOS Priority Map......................................................................................................... 55 13.6.8 TOSPMM – TOS Priority Map........................................................................................................ 55 13.6.9 TOSPMH – TOS Priority Map ........................................................................................................ 55 13.6.10 AVDM – VLAN Discard Map ........................................................................................................ 56 13.6.11 TOSDML – TOS Discard Map...................................................................................................... 56 13.6.12 BMRC - Broadcast/Multicast Rate Control................................................................................... 57 13.6.13 UCC – Unicast Congestion Control.............................................................................................. 57 13.6.14 MCC – Multicast Congestion Control ........................................................................................... 57 13.6.15 PR100 – Port Reservation for 10/100 ports ................................................................................. 58 13.6.16 PRG – Port Reservation for Giga ports........................................................................................ 58 13.6.17 SFCB – Share FCB Size.............................................................................................................. 59 13.6.18 C2RS – Class 2 Reserve Size ..................................................................................................... 59 13.6.19 C3RS – Class 3 Reserve Size ..................................................................................................... 59 13.6.20 C4RS – Class 4 Reserve Size ..................................................................................................... 59 13.6.21 C5RS – Class 5 Reserve Size ..................................................................................................... 59 13.6.22 C6RS – Class 6 Reserve Size ..................................................................................................... 60 13.6.23 C7RS – Class 7 Reserve Size ..................................................................................................... 60 13.6.24 Classes Byte Limit Set 0 .............................................................................................................. 60 13.6.25 Classes Byte Limit Set 1 .............................................................................................................. 60 13.6.26 Classes Byte Limit Set 2 .............................................................................................................. 60 13.6.27 Classes Byte Limit Set 3 .............................................................................................................. 61 13.6.28 Classes Byte Limit Giga Port 1 .................................................................................................... 61 13.6.29 Classes Byte Limit Giga Port 2 .................................................................................................... 61 13.6.30 Classes WFQ Credit Set 0 ........................................................................................................... 62 13.6.31 Classes WFQ Credit Set 1 ........................................................................................................... 62 13.6.32 Classes WFQ Credit Set 2 ........................................................................................................... 62 13.6.33 Classes WFQ Credit Set 3 ........................................................................................................... 63 13.6.34 Classes WFQ Credit Port G1 ....................................................................................................... 63 13.6.35 Classes WFQ Credit Port G2 ....................................................................................................... 63 13.6.36 Class 6 Shaper Control Port G1................................................................................................... 64 13.6.37 Class 6 Shaper Control Port G2................................................................................................... 64 13.6.38 RDRC0 – WRED Rate Control 0.................................................................................................. 64 13.6.39 RDRC1 – WRED Rate Control 1.................................................................................................. 64 13.6.40 User Defined Logical Ports and Well Known Ports ...................................................................... 65 13.7 Group 6 Address MISC Group ................................................................................................................ 70 13.7.1 MII_OP0 – MII Register Option 0 ................................................................................................... 70 13.7.2 MII_OP1 – MII Register Option 1 ................................................................................................... 70 Zarlink Semiconductor Inc. 5 MVTX2603 Data Sheet Table of Contents 13.7.3 FEN – Feature Register .................................................................................................................71 13.7.4 MIIC0 – MII Command Register 0..................................................................................................71 13.7.5 MIIC1 – MII Command Register 1..................................................................................................71 13.7.6 MIIC2 – MII Command Register 2..................................................................................................72 13.7.7 MIIC3 – MII Command Register 3..................................................................................................72 13.7.8 MIID0 – MII Data Register 0...........................................................................................................72 13.7.9 MIID1 – MII Data Register 1...........................................................................................................72 13.7.10 LED Mode – LED Control.............................................................................................................72 13.7.11 CHECKSUM - EEPROM Checksum ............................................................................................73 13.8 Group 7 Address Port Mirroring Group ...................................................................................................73 13.8.1 MIRROR1_SRC – Port Mirror source port .....................................................................................73 13.8.2 MIRROR1_DEST – Port Mirror destination....................................................................................74 13.8.3 MIRROR2_SRC – Port Mirror source port .....................................................................................74 13.8.4 MIRROR2_DEST – Port Mirror destination....................................................................................74 13.9 Group F Address CPU Access Group .....................................................................................................74 13.9.1 GCR-Global Control Register.........................................................................................................74 13.9.2 DCR-Device Status and Signature Register ..................................................................................75 13.9.3 DCR1-Giga port status ...................................................................................................................75 13.9.4 DPST – Device Port Status Register..............................................................................................76 13.9.5 DTST – Data read back register.....................................................................................................77 13.9.6 DA – DA Register ...........................................................................................................................77 13.10 TBI Registers .........................................................................................................................................77 13.10.1 Control Register ...........................................................................................................................77 13.10.2 Status Register.............................................................................................................................78 13.10.3 Advertisement Register ................................................................................................................78 13.10.4 Link Partner Ability Register .........................................................................................................79 13.10.5 Expansion Register ......................................................................................................................79 13.10.6 Extended Status Register.............................................................................................................80 14.0 BGA and Ball Signal Descriptions ............................................................................... 81 14.1 BGA Views...............................................................................................................................................81 14.1.1 Encapsulated View.........................................................................................................................81 14.1.2 Power and Ground Distribution ......................................................................................................82 14.2 Ball – Signal Descriptions ........................................................................................................................83 14.2.1 Ball Signal Descriptions..................................................................................................................83 14.3 Ball – Signal Name ..................................................................................................................................91 14.4 AC/DC Timing ..........................................................................................................................................97 14.4.1 Absolute Maximum Ratings............................................................................................................97 14.4.2 DC Electrical Characteristics..........................................................................................................98 14.4.3 Recommended Operation Conditions ............................................................................................98 14.5 Local Frame Buffer SBRAM Memory Interface........................................................................................98 14.5.1 Local SBRAM Memory Interface ....................................................................................................98 14.6 Local Switch Database SBRAM Memory Interface................................................................................100 14.6.1 Local SBRAM Memory Interface: .................................................................................................100 14.7 AC Characteristics .................................................................................................................................102 14.7.1 Reduced Media Independent Interface ........................................................................................102 14.7.2 LED Interface ...............................................................................................................................107 14.7.3 SCANLINK SCANCOL Output Delay Timing ...............................................................................107 14.7.4 MDIO Input Setup and Hold Timing .............................................................................................108 14.7.5 I2C Input Setup Timing.................................................................................................................109 14.7.6 Serial Interface Setup Timing .......................................................................................................110 6 Zarlink Semiconductor Inc. MVTX2603 Data Sheet List of Figures Figure 1 - MVTX2603AG System Block Diagram ...................................................................................................1 Figure 2 - Data Transfer Format for I2C Interface .................................................................................................12 Figure 3 - Write Command ....................................................................................................................................14 Figure 4 - Read Command ...................................................................................................................................14 Figure 5 - MVTX2603AG SRAM Interface Block Diagram (DMAs for 10/1000 Ports Only) ..................................16 Figure 6 - Memory Map .........................................................................................................................................17 Figure 7 - Priority Classification Rule ....................................................................................................................19 Figure 8 - Memory Configuration For: 2 banks, 1 layer, 2MB total .......................................................................22 Figure 9 - Memory Configuration For: 2 banks, 2 Layer, 4MB total ......................................................................22 Figure 10 - Memory Configuration For: 2 banks, 1 layer, 4MB .............................................................................22 Figure 11 - Memory Configuration For: 2 banks, 2 layers, 4MB total ....................................................................23 Figure 12 - Memory Configuration For: 2 banks, 1 layer, 4MB .............................................................................23 Figure 13 - Buffer Partition Scheme Used to Implement MVTX2603AG Buffer Management ..............................30 Figure 14 - TBI Connection ...................................................................................................................................35 Figure 15 - GPSI (7WS) mode connection diagram ..............................................................................................36 Figure 16 - SCAN LINK and SCAN COLLISON status diagram ...........................................................................37 Figure 17 - Timing Diagram of LED Interface .......................................................................................................38 Figure 18 - BGA View ...........................................................................................................................................81 Figure 19 - Power and Ground Distribution View ..................................................................................................82 Figure 20 - Local Memory Interface – Input setup and hold timing .......................................................................99 Figure 21 - Local Memory Interface - Output valid delay timing ............................................................................99 Figure 22 - Local Memory Interface – Input setup and hold timing .....................................................................100 Figure 23 - Local Memory Interface - Output valid delay timing ..........................................................................101 Figure 24 - AC Characteristics – Reduced Media Independent Interface ...........................................................102 Figure 25 - AC Characteristics – Reduced Media Independent Interface ...........................................................102 Figure 26 - AC Characteristics- GMII ..................................................................................................................103 Figure 27 - AC Characteristics – Gigabit Media Independent Interface ..............................................................103 Figure 28 - AC Characteristics – Gigabit Media Independent Interface ..............................................................103 Figure 29 - Gigabit TBI Interface Transmit Timing ..............................................................................................104 Figure 30 - Gigabit TBI Interface Receive Timing ...............................................................................................104 Figure 31 - AC Characteristics- GMII ..................................................................................................................105 Figure 32 - AC Characteristics – Gigabit Media Independent Interface ..............................................................105 Figure 33 - Gigabit TBI Interface Transmit Timing ..............................................................................................106 Figure 34 - Gigabit TBI Interface Timing .............................................................................................................106 Figure 35 - AC Characteristics – LED Interface ..................................................................................................107 Figure 36 - SCANLINK SCANCOL Output Delay Timing ....................................................................................107 Figure 37 - SCANLINK, SCANCOL Setup Timing ..............................................................................................107 Figure 38 - MDIO Input Setup and Hold Timing ..................................................................................................108 Figure 39 - MDIO Output Delay Timing ..............................................................................................................108 Figure 40 - I2C Input Setup Timing .....................................................................................................................109 Figure 41 - I2C Output Delay Timing ..................................................................................................................109 Figure 42 - Serial Interface Setup Timing ...........................................................................................................110 Figure 43 - Serial Interface Output Delay Timing ................................................................................................110 Zarlink Semiconductor Inc. 7 MVTX2603 8 Data Sheet Zarlink Semiconductor Inc. MVTX2603 Data Sheet List of Tables Table 1 - Memory Configuration ..........................................................................................................................17 Table 2 - PVMAP Register ...................................................................................................................................20 Table 3 - Supported Memory Configurations (Pipeline SBRAM Mode) ...............................................................20 Table 4 - Supported Memory Configurations (ZBT Mode) ...................................................................................21 Table 5 - Options for Memory Configuration ........................................................................................................21 Table 6 - Two-dimensional World Traffic .............................................................................................................25 Table 7 - Four QoS Configurations for a 10/100 Mbps Port ................................................................................26 Table 8 - Four QoS Configurations for a Gigabit Port ..........................................................................................27 Table 9 - WRED Drop Thresholds .......................................................................................................................29 Table 10 - Mapping between MVTX2603AG and IETF Diffserv Classes for Gigabit Ports ..................................32 Table 11 - Mapping between MVTX2603AG and IETF Diffserv Classes for 10/100 Ports ..................................32 Table 12 - MVTX2603AG Features Enabling IETF Diffserv Standards ...............................................................32 Table 13 - AC Characteristics – Local frame buffer SBRAM Memory Interface ...............................................100 Table 14 - AC Characteristics – Local Switch Database SBRAM Memory Interface .........................................101 Table 15 - AC Characteristics – Reduced Media Independent Interface ...........................................................102 Table 16 - Output Delay Timing .........................................................................................................................104 Table 17 - Input Setup Timing ............................................................................................................................104 Table 18 - AC Characteristics – Gigabit Media Independent Interface ..............................................................105 Table 19 - Output Delay Timing .........................................................................................................................106 Table 20 - Input Setup Timing ............................................................................................................................106 Table 21 - AC Characteristics – LED Interface ..................................................................................................107 Table 22 - SCANLINK, SCANCOL Timing .........................................................................................................108 Table 23 - MDIO Timing .....................................................................................................................................108 Table 24 - I2C Timing ........................................................................................................................................109 Table 25 - Serial Interface Timing ......................................................................................................................110 Zarlink Semiconductor Inc. 9 MVTX2603 10 Data Sheet Zarlink Semiconductor Inc. MVTX2603 Data Sheet 1.0 Block Functionality 1.1 Frame Data Buffer (FDB) Interfaces The FDB interface supports pipelined synchronrous burst SRAM (SBRAM) memory at 100 MHz. To ensure a non-blocking switch, two memory domains are required. Each domain has a 64 bit wide memory bus. At 100 MHz, the aggregate memory bandwidth is 12.8 Gbps, which is enough to support 24 10/100 Mbps and 2 Gigabit ports at full wire speed switching. For 24+ 2 stacking application, ZBT memory at 125 MHz is required. The Switching Database is also located in the external SBRAM; it is used for storing MAC addresses and their physical port number. It is duplicated and stored in both memory domains. Therefore, when the system updates the contents of the switching database, it has to write the entry to both domains at the same time. 1.2 GMII/PCS MAC Module (GMAC) The GMII/PCS Media Access Control (MAC) module provides the necessary buffers and control interface between the Frame Engine (FE) and the external physical device (PHY). The MVTX2603AG GMAC implements both GMII and MII interfaces, which offers a simple migration from 10/100 to 1G. The GMAC of the MVTX2603AG meets the IEEE 802.3Z specification. It is able to operate in 10M/100M either Half or Full Duplex mode with a back pressure/flow control mechanism or in 1G full duplex mode with flow control mechanism. Furthermore, it will automatically retransmit upon collision for up to 16 total transmissions. PHY addresses for GMAC are 01h and 02h. 1.3 Physical Coding Sublayer (PCI) Interface For the MVTX2603AG, the 1000BASE-X PCI Interface is designed internally and may be utilized in the absence of a GMII. The PCS incorporates all the functions required by the GMII to include encoding (decoding) 8B GMII data to (from) 8B/10B TBI format for PHY communication and generating Collision Detect (COL) signals for half-duplex mode. It also manages the Auto negotiation process by informing the management entity that the PHY is ready for communications. The on-chip TBI may be disabled if TBI exists within the Gigabit PHY. The TBI interface provides a uniform interface for all 1000 Mbps PHY implementations. The PCS comprises the PCS Transmit, Synchronization, PCS Receive, and Auto negotiation processes for 1000BASE-X. The PCS Transmit process sends the TBI signals TXD [9:0] to the physical medium and generates the GMII Collision Detect (COL) signal based on whether a reception is occurring simultaneously with transmission. Additionally, the Transmit process generates an internal “transmitting” flag and monitors Auto negotiation to determine whether to transmit data or to reconfigure the link. The PCS Synchronization process determines whether or not the receive channel is operational. The PCS Receive process generates RXD [7:0] on the GMII from the TBI data [9:0], and the internal “receiving” flag for use by the Transmit processes. The PCS Auto negotiation process allows the MVTX2603AG to exchange configuration information between two devices that share a link segment, and to automatically configure the link for the appropriate speed of operation for both devices. 1.4 10/100 MAC Module (RMAC) The 10/100 Media Access Control module provides the necessary buffers and control interface between the Frame Engine (FE) and the external physical device (PHY). The MVTX2603AG has two interfaces, RMII or Serial (only for 10M). The 10/100 MAC of the MVTX2603AG device meets the IEEE 802.3 specification. It is able to operate in either Half or Full Duplex mode with a back pressure/flow control mechanism. In addition, it will automatically retransmit upon collision for up to 16 total transmissions. The PHY address for 24 10/100 MAC are from 08h to 1fh. Zarlink Semiconductor Inc. 11 MVTX2603 1.5 Data Sheet Configuration Interface Module The MVTX2603AG supports a serial and an I2C interface, which provides an easy way to configure the system. Once configured, the resulting configuration can be stored in an I2C EEPROM. 1.6 Frame Engine The main function of the frame engine is to forward a frame to its proper destination port or ports. When a frame arrives, the frame engine parses the frame header (64 bytes) and formulates a switching request, which is sent to the search engine, to resolve the destination port. The arriving frame is moved to the FDB. After receiving a switch response from the search engine, the frame engine performs transmission scheduling based on the frame’s priority. The frame engine forwards the frame to the MAC module when the frame is ready to be sent. 1.7 Search Engine The Search Engine resolves the frame’s destination port or ports according to the destination MAC address (L2). It also performs MAC learning, priority assignment, and trunking functions. 1.8 LED Interface The LED interface provides a serial interface for carrying 24+2 port status signals. It can also provide direct status pins (6) for the two Gigabit ports. 1.9 Internal Memory Several internal tables are required and are described as follows: • Frame Control Block (FCB) - Each FCB entry contains the control information of the associated frame stored in the FDB, e.g. frame size, read/write pointer, transmission priority, etc. • MCT Link Table - The MCT Link Table stores the linked list of MCT entries that have collisions in the external MAC Table. The external MAC table is located in the FDB Memory. Note: the external MAC table is located in the external SBRAM Memory. 2.0 System Configuration 2.1 Configuration Mode The MVTX2603AG can be configured by EEPROM (24C02 or compatible) via an I2C interface at boot time, or via a synchronous serial interface during operation. I2C Interface 2.2 The I2C interface uses two bus lines, a serial data line (SDA) and a serial clock line (SCL). The SCL line carries the control signals that facilitate the transfer of information from EEPROM to the switch. Data transfer is 8-bit serial and bidirectional, at 50 Kbps. Data transfer is performed between master and slave IC using a request / acknowledgment style of protocol. The master IC generates the timing signals and terminates data transfer. Figure 2 depicts the data transfer format. START SLAVE ADDRESS R/W ACK DATA 1 (8 bits) ACK DATA 2 Figure 2 - Data Transfer Format for 2.2.1 I 2C ACK DATA M ACK STOP Interface Start Condition Generated by the master (in our case, the MVTX2603AG). The bus is considered to be busy after the Start condition is generated. The Start condition occurs if while the SCL line is High, there is a High-to-Low transition of the SDA line. Other than in the Start condition (and Stop condition), the data on the SDA line must be stable during the High period of SCL. The High or Low state of SDA can only change when SCL is Low. In addition, when the I2C bus is free, both lines are High. 12 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 2.2.2 Address The first byte after the Start condition determines which slave the master will select. The slave in our case is the EEPROM. The first seven bits of the first data byte make up the slave address. 2.2.3 Data Direction The eighth bit in the first byte after the Start condition determines the direction (R/W) of the message. A master transmitter sets this bit to W; a master receiver sets this bit to R. 2.2.4 Acknowledgment Like all clock pulses, the acknowledgment-related clock pulse is generated by the master. However, the transmitter releases the SDA line (High) during the acknowledgment clock pulse. Furthermore, the receiver must pull down the SDA line during the acknowledge pulse so that it remains stable Low during the High period of this clock pulse. An acknowledgment pulse follows every byte transfer. If a slave receiver does not acknowledge after any byte, then the master generates a Stop condition and aborts the transfer. If a master receiver does not acknowledge after any byte, then the slave transmitter must release the SDA line to let the master generate the Stop condition. 2.2.5 Data After the first byte containing the address, all bytes that follow are data bytes. Each byte must be followed by an acknowledge bit. Data is transferred MSB first. 2.2.6 Stop Condition Generated by the master. The bus is considered to be free after the Stop condition is generated. The Stop condition occurs if while the SCL line is High, there is a Low-to-High transition of the SDA line. The I2C interface serves the function of configuring the MVTX2603AG at boot time. The master is the MVTX2603AG, and the slave is the EEPROM memory. 2.3 Synchronous Serial Interface The synchronous serial interface serves the function of configuring the MVTX2603AG not at boot time but via a PC. The PC serves as master and the MVTX2603AG serves as slave. The protocol for the synchronous serial interface is nearly identical to the I2C protocol. The main difference is that there is no acknowledgment bit after each byte of data transferred. The unmanaged MVTX2603AG uses a synchronous serial interface to program the internal registers. To reduce the number of signals required, the register address, command and data are shifted in serially through the D0 pin. STROBE- pin is used as the shift clock. AUTOFD- pin is used as data return path. Each command consists of four parts. START pulse Register Address Read or Write command Data to be written or read back Any command can be aborted in the middle by sending a ABORT pulse to the MVTX2603AG. A START command is detected when D0 is sampled high when STROBE- rise and D0 is sampled low when STROBE- fall. Zarlink Semiconductor Inc. 13 MVTX2603 Data Sheet An ABORT command is detected when D0 is sampled low when STROBE- rise and D0 is sampled high when STROBE- fall. 2.3.1 Write Command STROBE2 extra clock cycles 2 Extra clocks after last after last transfer transfer D0 A2 A0 A1 A2 START A11 W ... A9 A9 A10 A10 A11 ... ADDRESS D0 D1 D1 D2 D2 D3 D3 D4 D4 D5 D5 D6 D6 D7 D7 D0 COMMAND DATA Figure 3 - Write Command 2.3.2 Read Command STROBE- A10 A11 A11 RR A0 A1 A1 A2 A0 A9 A10 A2 ...... A9 D0 START ADDRESS COMMAND DATA D0 D1 D2 D3 D4 D5 D5 D6 D7 AUTOFD- Figure 4 - Read Command All registers in MVTX2603AG can be modified through this synchronous serial interface. 2.4 Stacking The two Gigabits ports can be used as link between boxes. Each Gigabit port can be accelerated to 2 Gpbs if desired (in conjunction with ZBT memory domains at 125MHz). If both Gigabit ports are used for this purpose, this provides a total of 4 Gbps of bandwidth between devices. 3.0 MVTX2603AG Data Forwarding Protocol 3.1 Unicast Data Frame Forwarding When a frame arrives, it is assigned a handle in memory by the Frame Control Buffer Manager (FCB Manager). An FCB handle will always be available, because of advance buffer reservations. The memory (SRAM) interface consists of two 64-bit buses, connected to two SRAM banks, A and B. The Receive DMA (RxDMA) is responsible for multiplexing the data and the address. On a port’s “turn,” the RxDMA will move 8 bytes (or up to the end-of-frame) from the port’s associated RxFIFO into memory (Frame Data Buffer, or FDB). Once an entire frame has been moved to the FDB, and a good end-of-frame (EOF) has been received, the Rx interface makes a switch request. The RxDMA arbitrates among multiple switch requests. 14 Zarlink Semiconductor Inc. MVTX2603 Data Sheet The switch request consists of the first 64 bytes of a frame, containing among other things, the source and destination MAC addresses of the frame. The search engine places a switch response in the switch response queue of the frame engine when done. Among other information, the search engine will have resolved the destination port of the frame and will have determined that the frame is unicast. After processing the switch response, the Transmission Queue Manager (TxQ manager) of the frame engine is responsible for notifying the destination port that it has a frame to forward to it. But first, the TxQ manager has to decide whether or not to drop the frame, based on global FDB reservations and usage, as well as TxQ occupancy at the destination. If the frame is not dropped, then the TxQ manager links the frame’s FCB to the correct per-port-per-class TxQ. Unicast TxQ’s are linked lists of transmission jobs, represented by their associated frames’ FCB’s. There is one linked list for each transmission class for each port. There are 4 transmission classes for each of the 24 10/100 ports, and 8 classes for each of the two Gigabit ports – a total of 112 unicast queues. The TxQ manager is responsible for scheduling transmission among the queues representing different classes for a port. When the port control module determines that there is room in the MAC Transmission FIFO (TxFIFO) for another frame, it requests the handle of a new frame from the TxQ manager. The TxQ manager chooses among the head-of-line (HOL) frames from the per-class queues for that port, using a Zarlink Semiconductor scheduling algorithm. The Transmission DMA (TxDMA) is responsible for multiplexing the data and the address. On a port’s turn, the TxDMA will move 8 bytes (or up to the EOF) from memory into the port’s associated TxFIFO. After reading the EOF, the port control requests a FCB release for that frame. The TxDMA arbitrates among multiple buffer release requests. The frame is transmitted from the TxFIFO to the line. 3.2 Multicast Data Frame Forwarding After receiving the switch response, the TxQ manager has to make the dropping decision. A global decision to drop can be made, based on global FDB utilization and reservations. If so, then the FCB is released and the frame is dropped. In addition, a selective decision to drop can be made, based on the TxQ occupancy at some subset of the multicast packet’s destinations. If so, then the frame is dropped at some destinations but not others, and the FCB is not released. If the frame is not dropped at a particular destination port, then the TxQ manager formats an entry in the multicast queue for that port and class. Multicast queues are physical queues (unlike the linked lists for unicast frames). There are 2 multicast queues for each of the 24 10/100 ports. The queue with higher priority has room for 32 entries and the queue with lower priority has room for 64 entries. There are 4 multicast queues for each of the two Gigabit ports. The sizes of the queues are: 32 entries (higher priority queue, 32 entries, 32 entries and 64 entries (lower priority queue). There is one multicast queue for every two priority classes. For the 10/100 ports to map the 8 transmit priorities into 2 multicast queues, the 2 LSB are discarded. For the gigabit ports to map the 8 transmit priorities into 4 multicast queues, the LSB are discarded. During scheduling, the TxQ manager treats the unicast queue and the multicast queue of the same class as one logical queue. The older head of line of the two queues is forwarded first. The port control requests a FCB release only after the EOF for the multicast frame has been read by all ports to which the frame is destined. Zarlink Semiconductor Inc. 15 MVTX2603 Data Sheet 4.0 Memory Interface 4.1 Overview The MVTX2603AG provides two 64-bit wide SRAM banks, SRAM Bank A and SRAM Bank B, with a 64-bit bus connected to each. Each DMA can read and write from both bank A and bank B. The following figure provides an overview of the MVTX2603AG SRAM banks. SRAM Bank A TXDMA 0-7 TXDMA 8-15 SRAM Bank B TXDMA 16-23 RXDMA 0-7 RXDMA 8-15 RXDMA 16-23 Figure 5 - MVTX2603AG SRAM Interface Block Diagram (DMAs for 10/1000 Ports Only) 4.2 ZBT Support The MVTX2603AG supports Zero Bus Turnaround (ZBT). ZBT is a synchronous SRAM architecture that is optimized for networking and telecommunications applications. It can significantly increase the switch’s internal bandwidth when compared to standard Pipeline SyncBurst SRAM. The ZBT architecture is optimized for switching and other applications with highly random READs and WRITEs. ZBT SRAMs eliminate all idle cycles when turning the data bus around from a WRITE operation to a READ operation (or vice versa). This feature results in dramatic performance improvements in systems that have such traffic patterns (that is, frequent and random read and write access to the SRAM). Please refer to the ZBT Application note for further details. 4.3 Detailed Memory Information Because the bus for each bank is 64 bits wide, frames are broken into 8-byte granules, written to and read from memory. The first 8-byte granule gets written to Bank A, the second 8-byte granule gets written to Bank B, and so on in alternating fashion. When reading frames from memory, the same procedure is followed, first from A, then from B, and so on. The reading and writing from alternating memory banks can be performed with minimal waste of memory bandwidth. What’s the worst case? For any speed port, in the worst case, a 1-byte-long EOF granule gets written to Bank A. This means that a 7-byte segment of Bank A bandwidth is idle, and furthermore, the next 8byte segment of Bank B bandwidth is idle, because the first 8 bytes of the next frame will be written to Bank A, not B. This scenario results in a maximum 15 bytes of waste per frame, which is always acceptable because the interframe gap is 20 bytes. Search engine data is written to both banks in parallel. In this way, a search engine read operation can be performed by either bank at any time without a problem. 16 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 4.4 Memory Requirements To speed up searching and decrease memory latency, the external MCT database is duplicated in both memory banks. To support 64K MCT, 4 MB memory is required. Up to 2K frame buffers are supported and they will use 3 MB of memory. The maximum system memory requirement is 4 MB. If less memory is desired, the configuration can scale down proportionally. Bank A Bank B Frame Buffer Max MAC Address 1M 1M 1K 32K 2M 2M 2K 64k Table 1 - Memory Configuration 1M Bank A 1M Bank B 2M Bank A 2M Bank B 0.75M 0.75M 1.5M 1.5M 0.25M 0.25M 0.5M 0.5M Frame Data Buffer (FDR) Area MAC Address Control Table (MCT) Area Figure 6 - Memory Map 5.0 Search Engine 5.1 Search Engine Overview The MVTX2603AG search engine is optimized for high throughput searching, with enhanced features to support: • • • • • • 5.2 Up to 64K MAC addresses 3 groups of port trunking (1 for the two Gigabit ports, and 2 others) Traffic classification into 4 (or 8 for Gigabit) transmission priorities, and 2 drop precedence levels Flooding, Broadcast, Multicast Storm Control MAC address learning and aging Port based VLAN Basic Flow Shortly after a frame enters the MVTX2603AG and is written to the Frame Data Buffer (FDB), the frame engine generates a Switch Request, which is sent to the search engine. The switch request consists of the first 64 bytes of the frame, which contain all the necessary information for the search engine to perform its task. When the search engine is done, it writes to the Switch Response Queue, and the frame engine uses the information provided in that queue for scheduling and forwarding. In performing its task, the search engine extracts and compresses the useful information from the 64-byte switch request. Among the information extracted are the source and destination MAC addresses, the transmission and discard priorities, whether the frame is unicast or multicast. Requests are sent to the external SRAM to locate the associated entries in the external hash table. Zarlink Semiconductor Inc. 17 MVTX2603 Data Sheet When all the information has been collected from external SRAM, the search engine has to compare the MAC address on the current entry with the MAC address for which it is searching. If it is not a match, the process is repeated on the internal MCT Table. All MCT entries other than the first of each linked list are maintained internal to the chip. If the desired MAC address is still not found, then the result is either learning (source MAC address unknown) or flooding (destination MAC address unknown). In addition, port based VLAN information is used to select the correct set of destination ports for the frame (for multicast), or to verify that the frame’s destination port is associated with the VLAN (for unicast). If the destination MAC address belongs to a port trunk, then the trunk number is retrieved instead of the port number. But on which port of the trunk will the frame be transmitted? This is easily computed using a hash of the source and destination MAC addresses. When all the information is compiled, the switch response is generated, as stated earlier. 5.3 Search, Learning, and Aging 5.3.1 MAC Search The search block performs source MAC address and destination MAC address searching. As we indicated earlier, if a match is not found, then the next entry in the linked list must be examined, and so on until a match is found or the end of the list is reached. The port based VLAN bitmap is used to determine whether the frame should be forwarded to the outgoing port. When the egress port is not included in the ingress port VLAN bitmap, the packet is discarded. The MAC search block is also responsible for updating the source MAC address timestamp and the VLAN port association timestamp, used for aging. 5.3.2 Learning The learning module learns new MAC addresses and performs port change operations on the MCT database. The goal of learning is to update this database as the networking environment changes over time. Learning and port change will be performed based on memory slot availability only. 5.3.3 Aging Aging time is controlled by register 400h and 401h. The aging module scans and ages MCT entries based on a programmable “age out” time interval. As we indicated earlier, the search module updates the source MAC address timestamps for each frame it processes. When an entry is ready to be aged, the entry is removed from the table. 5.4 Quality of Service Quality of Service (QoS) refers to the ability of a network to provide better service to selected network traffic over various technologies. Primary goals of QoS include dedicated bandwidth, controlled jitter and latency (required by some real-time and interactive traffic), and improved loss characteristics. Traditional Ethernet networks have had no prioritization of traffic. Without a protocol to prioritize or differentiate traffic, a service level known as “best effort” attempts to get all the packets to their intended destinations with minimum delay; however, there are no guarantees. In a congested network or when a low-performance switch/router is overloaded, “best effort” becomes unsuitable for delay-sensitive traffic and mission-critical data transmission. The advent of QoS for packet-based systems accommodates the integration of delay-sensitive video and multimedia traffic onto any existing Ethernet network. It also alleviates the congestion issues that have previously plagued such “best effort” networking systems. QoS provides Ethernet networks with the breakthrough technology to prioritize traffic and ensure that a certain transmission will have a guaranteed minimum amount of bandwidth. 18 Zarlink Semiconductor Inc. MVTX2603 Data Sheet Extensive core QoS mechanisms are built into the MVTX2603AG architecture to ensure policy enforcement and buffering of the ingress port, as well as weighted fair-queue (WFQ) scheduling at the egress port. In the MVTX2603AG, QoS-based policies sort traffic into a small number of classes and mark the packets accordingly. The QoS identifier provides specific treatment to traffic in different classes, so that different quality of service is provided to each class. Frame and packet scheduling and discarding policies are determined by the class to which the frames and packets belong. For example, the overall service given to frames and packets in the premium class will be better than that given to the standard class; the premium class is expected to experience lower loss rate or delay. The MVTX2603AG supports the following QoS techniques: • • • • 5.5 In a port-based setup, any station connected to the same physical port of the switch will have the same transmit priority. In a tag-based setup, a 3-bit field in the VLAN tag provides the priority of the packet. This priority can be mapped to different queues in the switch to provide QoS. In a TOS/DS-based set up, TOS stands for “Type of Service” that may include “minimize delay,” “maximize throughput,” or “maximize reliability.” Network nodes may select routing paths or forwarding behaviours that are suitably engineered to satisfy the service request. In a logical port-based set up, a logical port provides the application information of the packet. Certain applications are more sensitive to delays than others; using logical ports to classify packets can help speed up delay sensitive applications, such as VoIP. Priority Classification Rule Figure 7 on page 19 shows the MVTX2603AG priority classification rule Yes Use Default Port Settings Fix Port Priority ? No TOS Precedence over VLAN? (FCR Register, Bit 7) Use Default Port Settings No No No IP Yes Yes VLAN Tag ? No IP Frame ? Yes Yes Use Logical Port No Use TOS Yes Use VLAN Priority Use Logical Port Figure 7 - Priority Classification Rule Zarlink Semiconductor Inc. 19 MVTX2603 5.6 Data Sheet Port Based VLAN An administrator can use the PVMAP Registers to configure the MVTX2603AG for port-based VLAN. For example, ports 1-3 might be assigned to the Marketing VLAN, ports 4-6 to the Engineering VLAN, and ports 7-9 to the Administrative VLAN. The MVTX2603AG determines the VLAN membership of each packet by noting the port on which it arrives. From there, the MVTX2603AG determines which outgoing port(s) is/are eligible to transmit each packet, or whether the packet should be discarded. Destination Port Numbers Bit Map Port Registers 26 Register for Port #0 PVMAP00_0[7:0] to PVMAP00_3[2:0] … 2 1 0 0 1 1 0 Register for Port #1 PVMAP01_0[7:0] to PVMAP01_3[2:0] 0 1 0 1 Register for Port #2 PVMAP02_0[7:0] to PVMAP02_3[2:0] 0 0 0 0 0 0 0 0 … Register for Port #26 PVMAP26_0[7:0] to PVMAP26_3[2:0] Table 2 - PVMAP Register For example, in the above table, a 1 denotes that an outgoing port is eligible to receive a packet from an incoming port. A 0 (zero) denotes that an outgoing port is not eligible to receive a packet from an incoming port. In this example • • • Data packets received at port #0 are eligible to be sent to outgoing ports 1 and 2 Data packets received at port #1 are eligible to be sent to outgoing ports 0, and 2 Data packets received at port #2 are not eligible to be sent to ports 0 and 1 5.7 Memory Configurations The MVTX2603AG supports the following memory configurations. SBRAM modes support 1M and 2M configurations, while ZBT mode supports 4M configurations, 2M per domain (bank). For detail connection information, please reference the memory application note. 1 M per bank (Bootstrap pin TSTOUT7 = open) Configuration Single Layer (Bootstrap pin TSTOUT13 = open) Double Layer (Bootstrap pin TSTOUT13 = pull down) Two 128K x 32 SRAM/bank or 2 M per bank (Bootstrap pin TSTOUT7 = pull down) Connections Two 256K x 32 SRAM/bank Connect 0E# and WE# Four 128K x 32 SRAM/bank or Connect 0E0# and WE0# Connect 0E1# and WE1# One 128 K x 64 SRAM/bank NA Two 128 K x 64 SRAM/bank Table 3 - Supported Memory Configurations (Pipeline SBRAM Mode) 20 Zarlink Semiconductor Inc. MVTX2603 Data Sheet Configuration 2 M per bank Connections Single Layer (Bootstrap pin TSTOUT13 = open) Two 256 K x 32 ZBT SRAM/bank or One 256 K x 64 ZBT SRAM/bank Connect ADS# to Layer 0 chipselect pin Double Layer (Bootstrap pin TSTOUT13 = pull down) Four 128 K x 32 ZBT SRAM/bank or Two 128 K x 64 ZBT SRAM/bank Connect ADS# to Layer 0 chipselect pin and 0E# to Layer 1 chipselect pin Table 4 - Supported Memory Configurations (ZBT Mode) Frame data Buffer Only Bank A 1M (SRAM) 2M (SRAM) MVTX2601 X X MVTX2602 X X Bank A and Bank B MVTX2603 1M/bank (SRAM) 2M/bank (SRAM) 1M/bank (ZBT SRAM) 2M/bank (ZBT SRAM) X X X X X (125Mhz) X (125Mhz) X X X (125Mhz) X (125Mhz) MVTX2603 (Gigabit ports in 2giga mode) MVTX2604 Bank A and Bank B X X MVTX2604 (Gigabit ports in 2giga mode) Table 5 - Options for Memory Configuration Bank A (1M One Layer) Bank B (1M One Layer) Data LA_D[63:32] Data LB_D[63:32] Data LB_D[31:0] Data LA_D[31:0] SRAM Memory 128K 32 bits SRAM Memory 128K 32 bits Memory 128K 32 bits Address LB_A[19:3] Address LA_A[19:3] B t t TSTOUT7 O TSTOUT13 Memory 128K 32 bits O TSTOUT4 O Zarlink Semiconductor Inc. 21 MVTX2603 Data Sheet Figure 8 - Memory Configuration For: 2 banks, 1 layer, 2MB total BANK A (2M Two Layers) BANK B (2M Two Layers) Data LA_D[63:32] Data LA_D[31:0] Data LB_D[63:32] SRAM Memory 128 K 32 bits SRAM Memory 128 K 32 bits SRAM Memory 128 K 32 bits SRAM Memory 128 K 32 bits Data LB_D[31:0] Address LA_A[19:3] SRAM Memory 128 K 32 bits SRAM Memory 128 K 32 bits SRAM Memory 128 K 32 bits SRAM Memory 128 K 32 bits Address LB_A[19:3] Bootstraps: TSTOUT7 = Pull Down, TSTOUT13 = Pull Down, TSTOUT4 = Open M 9 - Memory C fi Configuration ti F 2 b For: k 22 Lbanks,4MB t t l 4MB total Figure 2 Layer, BANK A (2M One Layer) BANK B (2M One Layer) Data LA_D[63:32] Data LA_D[31:0] SRAM Memory 256 K 32 bits Data LB_D[63:32] Data LB_D[31:0] Memory 256 K 32 bits Address LA_A[20:3] SRAM Memory 256 K 32 bits Address LB_A[20:3] Bootstraps: TSTOUT7 = Pull Down, TSTOUT13 = Open, TSTOUT4 = Open Figure 10 - Memory Configuration For: 2 banks, 1 layer, 4MB 22 Zarlink Semiconductor Inc. Memory 256 K 32 bits MVTX2603 Data Sheet BANK A (2M Two Layers) BANK B (2M Two Layers) Data LA_D[63:32] Data LA_D[31:0] Data LB_D[63:32] ZBT Memory 128 K 32 bits ZBT Memory 128 K 32 bits ZBT Memory 128 K 32 bits ZBT Memory 128 K 32 bits Data LB_D[31:0] Address LA_A[19:3] ZBT Memory 128 K 32 bits ZBT Memory 128 K 32 bits ZBT Memory 128 K 32 bits ZBT Memory 128 K 32 bits Address LB_A[19:3] Figure 11 - Memory Configuration For: 2 banks, 2 layers, 4MB total BANK A (2M One Layer) BANK B (2M One Layer) Data LA_D[63:32] Data LA_D[31:0] ZBT Memory 256 K 32 bits Data LB_D[63:32] ZBT Memory 256 K 32 bits Data LB_D[31:0] Address LA_A[20:3] ZBT Memory 256 K 32 bits ZBT Memory 256 K 32 bits Address LB_A[20:3] Bootstraps: TSTOUT7 = Pull Down, TSTOUT13 = Open, TSTOUT4 = Pull Down Figure 12 - Memory Configuration For: 2 banks, 1 layer, 4MB Zarlink Semiconductor Inc. 23 MVTX2603 6.0 Frame Engine 6.1 Data Forwarding Summary • • • • • • Data Sheet When a frame enters the device at the RxMAC, the RxDMA will move the data from the MAC RxFIFO to the FDB. Data is moved in 8-byte granules in conjunction with the scheme for the SRAM interface. A switch request is sent to the Search Engine. The Search Engine processes the switch request. A switch response is sent back to the Frame Engine and indicates whether the frame is unicast or multicast, and its destination port or ports. A Transmission Scheduling Request is sent in the form of a signal notifying the TxQ manager. Upon receiving a Transmission Scheduling Request, the device will format an entry in the appropriate Transmission Scheduling Queue (TxSch Q) or Queues. There are 4 TxSch Q for each 10/100 port (and 8 per Gigabit port), one for each priority. Creation of a queue entry either involves linking a new job to the appropriate linked list if unicast, or adding an entry to a physical queue if multicast. When the port is ready to accept the next frame, the TxQ manager will get the head-of-line (HOL) entry of one of the TxSch Qs, according to the transmission scheduling algorithm (to ensure per-class quality of service). The unicast linked list and the multicast queue for the same port-class pair are treated as one logical queue. The older HOL between the two queues goes first. For 10/100 ports multicast queue 0 is associated with unicast queue 0 and multicast queue 1 is associated with unicast queue 2. For Gigabit ports multicast queue 0 is associated with unicast queue 0, multicast queue 1 with unicast queue 2, multicast queue 2 with unicast queue 4 and multicast queue 3 with unicast queue 6. The TxDMA will pull frame data from the memory and forward it granule-by-granule to the MAC TxFIFO of the destination port. 6.2 Frame Engine Details This section briefly describes the functions of each of the modules of the MVTX2603AG frame engine. 6.2.1 FCB Manager The FCB manager allocates FCB handles to incoming frames, and releases FCB handles upon frame departure. The FCB manager is also responsible for enforcing buffer reservations and limits. The default values can be determined by referring to Chapter 8. In addition, the FCB manager is responsible for buffer aging, and for linking unicast forwarding jobs to their correct TxSch Q. The buffer aging can be enabled or disabled by the bootstrap pin and the aging time is defined in register FCBAT. 6.2.2 Rx Interface The Rx interface is mainly responsible for communicating with the RxMAC. It keeps track of the start and end of frame and frame status (good or bad). Upon receiving an end of frame that is good, the Rx interface makes a switch request. 6.2.3 RxDMA The RxDMA arbitrates among switch requests from each Rx interface. It also buffers the first 64 bytes of each frame for use by the search engine when the switch request has been made. 6.2.4 TxQ Manager First, the TxQ manager checks the per-class queue status and global reserved resource situation, and using this information, makes the frame dropping decision after receiving a switch response. If the decision is not to drop, the TxQ manager requests that the FCB manager link the unicast frame’s FCB to the correct per-port-perclass TxQ. If multicast, the TxQ manager writes to the multicast queue for that port and class. The TxQ manager can also trigger source port flow control for the incoming frame’s source if that port is flow control enabled. Second, the TxQ manager handles transmission scheduling; it schedules transmission among the queues representing different classes for a port. Once a frame has been scheduled, the TxQ manager reads the FCB information and writes to the correct port control module. 24 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 6.3 Port Control The port control module calculates the SRAM read address for the frame currently being transmitted. It also writes start of frame information and an end of frame flag to the MAC TxFIFO. When transmission is done, the port control module requests that the buffer be released. 6.4 TxDMA The TxDMA multiplexes data and address from port control, and arbitrates among buffer release requests from the port control modules. 7.0 Quality of Service and Flow Control 7.1 Model Quality of service is an all-encompassing term for which different people have different interpretations. In general, the approach to quality of service described here assumes that we do not know the offered traffic pattern. We also assume that the incoming traffic is not policed or shaped. Furthermore, we assume that the network manager knows his applications, such as voice, file transfer, or web browsing, and their relative importance. The manager can then subdivide the applications into classes and set up a service contract with each. The contract may consist of bandwidth or latency assurances per class. Sometimes it may even reflect an estimate of the traffic mix offered to the switch. As an added bonus, although we do not assume anything about the arrival pattern, if the incoming traffic is policed or shaped, we may be able to provide additional assurances about our switch’s performance. Table 6 on page 25 shows examples of QoS applications with three transmission priorities, but best effort (P0) traffic may form a fourth class with no bandwidth or latency assurances. Gigabit ports actually have eight total transmission priorities. Goals Total Assured Bandwidth (user defined) Low Drop Probability (low-drop) High Drop Probability (high-drop) Highest transmission priority, P3 50 Mbps Apps: phone calls, circuit emulation. Latency: < 1 ms. Drop: No drop if P3 not oversubscribed. Apps: training video. Latency: < 1 ms. Drop: No drop if P3 not oversubscribed; first P3 to drop otherwise. Middle transmission priority, P2 37.5 Mbps Apps: interactive apps, Web business. Latency: < 4-5 ms. Drop: No drop if P2 not oversubscribed. Apps: non-critical interactive apps. Latency: < 4-5 ms. Drop: No drop if P2 not oversubscribed; firstP2 to drop otherwise. Low transmission priority, P1 12.5 Mbps Apps: emails, file backups. Latency: < 16 ms desired, but not critical. Drop: No drop if P1 not oversubscribed. Apps: casual web browsing. Latency: < 16 ms desired, but not critical. Drop: No drop if P1 not oversubscribed; first to drop otherwise. Total 100 Mbps Table 6 - Two-dimensional World Traffic Zarlink Semiconductor Inc. 25 MVTX2603 Data Sheet A class is capable of offering traffic that exceeds the contracted bandwidth. A well-behaved class offers traffic at a rate no greater than the agreed-upon rate. By contrast, a misbehaving class offers traffic that exceeds the agreed-upon rate. A misbehaving class is formed from an aggregation of misbehaving microflows. To achieve high link utilization, a misbehaving class is allowed to use any idle bandwidth. However, such leniency must not degrade the quality of service (QoS) received by well-behaved classes. As Table 6 illustrates, the six traffic types may each have their own distinct properties and applications. As shown, classes may receive bandwidth assurances or latency bounds. In the table, P3, the highest transmission class, requires that all frames be transmitted within 1 ms, and receives 50% of the 100 Mbps of bandwidth at that port. Best-effort (P0) traffic forms a fourth class that only receives bandwidth when none of the other classes have any traffic to offer. It is also possible to add a fourth class that has strict priority over the other three; if this class has even one frame to transmit, then it goes first. In the MVTX2603AG, each 10/100 Mbps port will support four total classes, and each 1000 Mbps port will support eight classes. We will discuss the various modes of scheduling these classes in the next section. In addition, each transmission class has two subclasses, high-drop and low-drop. Well-behaved users should rarely lose packets. But poorly behaved users – users who send frames at too high a rate – will encounter frame loss, and the first to be discarded will be high-drop. Of course, if this is insufficient to resolve the congestion, eventually some low-drop frames are dropped, and then all frames in the worst case. Table 6 shows that different types of applications may be placed in different boxes in the traffic table. For example, casual web browsing fits into the category of high-loss, high-latency-tolerant traffic, whereas VoIP fits into the category of low-loss, low-latency traffic. 7.2 Four QoS Configurations There are four basic pieces to QoS scheduling in the MVTX2603AG: strict priority (SP), delay bound, weighted fair queuing (WFQ), and best effort (BE). Using these four pieces, there are four different modes of operation, as shown in Table 4, “Supported Memory Configurations (ZBT Mode),” and Table 6, “Two-dimensional World Traffic,” . For 10/100 Mbps ports, these modes are selected by the following registers: QOSC24 [7:6] CREDIT_C00 QOSC28 [7:6] CREDIT_C10 QOSC32 [7:6] CREDIT_C20 QOSC36 [7:6] CREDIT_C30 P3 P2 Op1 (default) Delay Bound Op2 SP Delay Bound Op3 SP WFQ Op4 WFQ P1 BE Table 7 - Four QoS Configurations for a 10/100 Mbps Port 26 P0 Zarlink Semiconductor Inc. BE MVTX2603 Data Sheet These modes are selected by QOSC40 [7:6] and QOSC48 [7:6] for the first and second gigabit ports, respectively. P7 P6 P5 Op1 (default) Delay Bound Op2 SP Delay Bound Op3 SP WFQ Op4 WFQ P4 P3 P2 P1 P0 BE BE Table 8 - Four QoS Configurations for a Gigabit Port The default configuration for a 10/100 Mbps port is three delay-bounded queues and one best-effort queue. The delay bounds per class are 0.8 ms for P3, 2 ms for P2, and 12.8 ms for P1. For a 1 Gbps port, we have a default of six delay-bounded queues and two best-effort queues. The delay bounds for a 1 Gbps port are 0.16 ms for P7 and P6, 0.32 ms for P5, 0.64 ms for P4, 1.28 ms for P3, and 2.56 ms for P2. Best effort traffic is only served when there is no delay-bounded traffic to be served. For a 1 Gbps port, where there are two best-effort queues, P1 has strict priority over P0. We have a second configuration for a 10/100 Mbps port in which there is one strict priority queue, two delay bounded queues, and one best effort queue. The delay bounds per class are 3.2 ms for P2 and 12.8 ms for P1. If the user is to choose this configuration, it is important that P3 (SP) traffic be either policed or implicitly bounded (e.g. if the incoming P3 traffic is very light and predictably patterned). Strict priority traffic, if not admission-controlled at a prior stage to the MVTX2603AG, can have an adverse effect on all other classes’ performance. For a 1 Gbps port, P7 and P6 are both SP classes, and P7 has strict priority over P6. In this case, the delay bounds per class are 0.32 ms for P5, 0.64 ms for P4, 1.28 ms for P3, and 2.56 ms for P2. The third configuration for a 10/100 Mbps port contains one strict priority queue and three queues receiving a bandwidth partition via WFQ. As in the second configuration, strict priority traffic needs to be carefully controlled. In the fourth configuration, all queues are served using a WFQ service discipline. 7.3 Delay Bound In the absence of a sophisticated QoS server and signaling protocol, the MVTX2603AG may not know the mix of incoming traffic ahead of time. To cope with this uncertainty, our delay assurance algorithm dynamically adjusts its scheduling and dropping criteria, guided by the queue occupancies and the due dates of their headof-line (HOL) frames. As a result, we assure latency bounds for all admitted frames with high confidence, even in the presence of system-wide congestion. Our algorithm identifies misbehaving classes and intelligently discards frames at no detriment to well-behaved classes. Our algorithm also differentiates between high-drop and low-drop traffic with a weighted random early drop (WRED) approach. Random early dropping prevents congestion by randomly dropping a percentage of high-drop frames even before the chip’s buffers are completely full, while still largely sparing low-drop frames. This allows high-drop frames to be discarded early, as a sacrifice for future low-drop frames. Finally, the delay bound algorithm also achieves bandwidth partitioning among classes. 7.4 Strict Priority and Best Effort When strict priority is part of the scheduling algorithm, if a queue has even one frame to transmit, it goes first. Two of our four QoS configurations include strict priority queues. The goal is for strict priority classes to be used for IETF expedited forwarding (EF), where performance guarantees are required. As we have indicated, it is important that strict priority traffic be either policed or implicitly bounded, so as to keep from harming other traffic classes. When best effort is part of the scheduling algorithm, a queue only receives bandwidth when none of the other classes have any traffic to offer. Two of our four QoS configurations include best effort queues. The goal is for best effort classes to be used for non-essential traffic, because we provide no assurances about best effort Zarlink Semiconductor Inc. 27 MVTX2603 Data Sheet performance. However, in a typical network setting, much best effort traffic will indeed be transmitted, and with an adequate degree of expediency. Because we do not provide any delay assurances for best effort traffic, we do not enforce latency by dropping best effort traffic. Furthermore, because we assume that strict priority traffic is carefully controlled before entering the MVTX2603AG, we do not enforce a fair bandwidth partition by dropping strict priority traffic. To summarize, dropping to enforce bandwidth or delay does not apply to strict priority or best effort queues. We only drop frames from best effort and strict priority queues when global buffer resources become scarce. 7.5 Weighted Fair Queuing In some environments – for example, in an environment in which delay assurances are not required, but precise bandwidth partitioning on small time scales is essential, WFQ may be preferable to a delay-bounded scheduling discipline. The MVTX2603AG provides the user with a WFQ option with the understanding that delay assurances can not be provided if the incoming traffic pattern is uncontrolled. The user sets four WFQ “weights” (eight for Gigabit ports) such that all weights are whole numbers and sum to 64. This provides per-class bandwidth partitioning with error within 2%. In WFQ mode, though we do not assure frame latency, the MVTX2603AG still retains a set of dropping rules that helps to prevent congestion and trigger higher level protocol end-to-end flow control. As before, when strict priority is combined with WFQ, we do not have special dropping rules for the strict priority queues, because the input traffic pattern is assumed to be carefully controlled at a prior stage. However, we do indeed drop frames from SP queues for global buffer management purposes. In addition, queue P0 for a 10/100 port (and queues P0 and P1 for a Gigabit port) are treated as best effort from a dropping perspective, though they still are assured a percentage of bandwidth from a WFQ scheduling perspective. What this means is that these particular queues are only affected by dropping when the global buffer count becomes low. 7.6 Shaper Although traffic shaping is not a primary function of the MVTX2603AG, the chip does implement a shaper for expedited forwarding (EF). Our goal in shaping is to control the peak and average rate of traffic exiting the MVTX2603AG. Shaping is limited to the two Gigabit ports only, and only to class P6 (the second highest priority). This means that class P6 will be the class used for EF traffic. If shaping is enabled for P6, then P6 traffic must be scheduled using strict priority. With reference to Table 8 only the middle two QoS configurations may be used. Peak rate is set using a programmable whole number, no greater than 64. For example, if the setting is 32, then the peak rate for shaped traffic is 32/64 * 1000 Mbps = 500 Mbps. Average rate is also a programmable whole number, no greater than 64, and no greater than the peak rate. For example, if the setting is 16, then the average rate for shaped traffic is 16/64 * 1000 Mbps = 250 Mbps. As a consequence of the above settings in our example, shaped traffic will exit the MVTX2603AG at a rate always less than 500 Mbps, and averaging no greater than 250 Mbps. See Programming QoS Registers application note for more information. Also, when shaping is enabled, it is possible for a P6 queue to explode in length if fed by a greedy source. The reason is that a shaper is by definition not work-conserving; that is, it may hold back from sending a packet even if the line is idle. Though we do have global resource management, we do nothing to prevent this situation locally. We assume SP traffic is policed at a prior stage to the MVTX2603AG. 28 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 7.7 WRED Drop Threshold Management Support To avoid congestion, the Weighted Random Early Detection (WRED) logic drops packets according to specified parameters. The following table summarizes the behavior of the WRED logic. Table 9 - WRED Drop Thresholds Px is the total byte count, in the priority queue x. The WRED logic has three drop levels, depending on the value of N, which is based on the number of bytes in the priority queues. If delay bound scheduling is used, N equals P3*16+P2*4+P1. If using WFQ scheduling, N equals P3+P2+P1. Each drop level from one to three has defined high-drop and low-drop percentages, which indicate the minimum and maximum percentages of the data that can be discarded. The X, Y Z percent can be programmed by the register RDRC0, RDRC1. In Level 3, all packets are dropped if the bytes in each priority queue exceed the threshold. Parameters A, B, C are the byte count thresholds for each priority queue. They can be programmed by the QOS control register (refer to the register group 5.) 7.8 Buffer Management Because the number of FDB slots is a scarce resource, and because we want to ensure that one misbehaving source port or class cannot harm the performance of a well-behaved source port or class, we introduce the concept of buffer management into the MVTX2603AG. Our buffer management scheme is designed to divide the total buffer space into numerous reserved regions and one shared pool, as shown in Figure 13 on page 30. As shown in the figure, the FDB pool is divided into several parts. A reserved region for temporary frames stores frames prior to receiving a switch response. Such a temporary region is necessary, because when the frame first enters the MVTX2603AG, its destination port and class are as yet unknown, and so the decision to drop or not needs to be temporarily postponed. This ensures that every frame can be received first before subjecting them to the frame drop discipline after classifying. Six reserved sections, one for each of the first six priority classes, ensure a programmable number of FDB slots per class. The lowest two classes do not receive any buffer reservation. Furthermore, even for 10/100 Mbps ports, a frame is stored in the region of the FDB corresponding to its class. As we have indicated, the eight classes use only four transmission scheduling queues for 10/100 Mbps ports, but as far as buffer usage is concerned, there are still eight distinguishable classes. Another segment of the FDB reserves space for each of the 26 ports ethernet port. Two parameters can be set, one for the source port reservation for 10/100 Mbps ports, and one for the source port reservation for 1 Gbps ports. These 26 reserved regions make sure that no well-behaved source port can be blocked by another misbehaving source port. In addition, there is a shared pool, which can store any type of frame. The frame engine allocates the frames first in the six priority sections. When the priority section is full or the packet has priority 1 or 0, the frame is allocated in the shared poll. Once the shared poll is full the frames are allocated in the section reserved for the source port. Zarlink Semiconductor Inc. 29 MVTX2603 Data Sheet The following registers define the size of each section of the frame data buffer: PR100- Port Reservation for 10/100 Ports PRG- Port Reservation for Giga Ports SFCB- Share FCB Size C2RS- Class 2 Reserve Size C3RS- Class 3 Reserve Size C4RS- Class 4 Reserve Size C5RS- Class 5 Reserve Size C6RS- Class 6 Reserve Size C7RS- Class 7 Reserve Size temporary reservation shared pool S per-class reservation per-source reservations (24 10/100M, CPU) per-source reservations (2G) Figure 13 - Buffer Partition Scheme Used to Implement MVTX2603AG Buffer Management 7.8.1 Dropping When Buffers Are Scarce Summarizing the two examples of local dropping discussed earlier in this chapter: • If a queue is a delay-bounded queue, we have a multi-level WRED drop scheme, designed to control delay and partition bandwidth in case of congestion. • If a queue is a WFQ-scheduled queue, we have a multi-level WRED drop scheme, designed to prevent congestion. In addition to these reasons for dropping, we also drop frames when global buffer space becomes scarce. The function of buffer management is to make sure that such dropping causes as little blocking as possible. 30 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 7.9 MVTX2603AG Flow Control Basics Because frame loss is unacceptable for some applications, the MVTX2603AG provides a flow control option. When flow control is enabled, scarcity of buffer space in the switch may trigger a flow control signal; this signal tells a source port that is sending a packet to this switch, to temporarily hold off. While flow control offers the clear benefit of no packet loss, it also introduces a problem for quality of service. When a source port receives an Ethernet flow control signal, all microflows originating at that port, well-behaved or not, are halted. A single packet destined for a congested output can block other packets destined for uncongested outputs. The resulting head-of-line blocking phenomenon means that quality of service cannot be assured with high confidence when flow control is enabled. In the MVTX2603AG, each source port can independently have flow control enabled or disabled. For flow control enabled ports, by default all frames are treated as lowest priority during transmission scheduling. This is done so that those frames are not exposed to the WRED Dropping scheme. Frames from flow control enabled ports feed to only one queue at the destination, the queue of lowest priority. What this means is that if flow control is enabled for a given source port, then we can guarantee that no packets originating from that port will be lost, but at the possible expense of minimum bandwidth or maximum delay assurances. In addition, these “downgraded” frames may only use the shared pool or the per-source reserved pool in the FDB; frames from flow control enabled sources may not use reserved FDB slots for the highest six classes (P2-P7). The MVTX2603AG does provide a system-wide option of permitting normal QoS scheduling (and buffer use) for frames originating from flow control enabled ports. When this programmable option is active, it is possible that some packets may be dropped, even though flow control is on. The reason is that intelligent packet dropping is a major component of the MVTX2603AG’s approach to ensuring bounded delay and minimum bandwidth for high priority flows. 7.9.1 Unicast Flow Control For unicast frames, flow control is triggered by source port resource availability. Recall that the MVTX2603AG’s buffer management scheme allocates a reserved number of FDB slots for each source port. If a programmed number of a source port’s reserved FDB slots have been used, then flow control Xoff is triggered. Xon is triggered when a port is currently being flow controlled, and all of that port’s reserved FDB slots have been released. Note that the MVTX2603AG’s per-source-port FDB reservations assure that a source port that sends a single frame to a congested destination will not be flow controlled. 7.9.2 Multicast Flow Control In unmanaged mode, flow control for multicast frames is triggered by a global buffer counter. When the system exceeds a programmable threshold of multicast packets, Xoff is triggered. Xon is triggered when the system returns below this threshold. In managed mode, per-VLAN flow control is used for multicast frames. In this case, flow control is triggered by congestion at the destination. How so? The MVTX2603AG checks each destination to which a multicast packet is headed. For each destination port, the occupancy of the lowest-priority transmission multicast queue (measured in number of frames) is compared against a programmable congestion threshold. If congestion is detected at even one of the packet’s destinations, then Xoff is triggered. In addition, each source port has a 26-bit port map recording which port or ports of the multicast frame’s fanout were congested at the time Xoff was triggered. All ports are continuously monitored for congestion, and a port is identified as uncongested when its queue occupancy falls below a fixed threshold. When all those ports that were originally marked as congested in the port map have become uncongested, then Xon is triggered, and the 26-bit vector is reset to zero. The MVTX2603AG also provides the option of disabling VLAN multicast flow control. Zarlink Semiconductor Inc. 31 MVTX2603 Data Sheet Note: If per-Port flow control is on, QoS performance will be affected. To determine the most efficient way to program, please refer to the QoS Application Note. 7.10 Mapping to IETF Diffserv Classes The mapping between priority classes discussed in this chapter and elsewhere is shown below. VTX P7 P6 P5 P4 P3 P2 P1 P0 IETF NM EF AF0 AF1 AF2 AF3 BE0 BE1 Table 10 - Mapping between MVTX2603AG and IETF Diffserv Classes for Gigabit Ports As the table illustrates, P7 is used solely for network management (NM) frames. P6 is used for expedited forwarding service (EF). Classes P2 through P5 correspond to an assured forwarding (AF) group of size 4. Finally, P0 and P1 are two best effort (BE) classes. For 10/100 Mbps ports, the classes of Table 12 are merged in pairs—one class corresponding to NM+EF, two AF classes, and a single BE class. VTX P3 P2 P1 P0 IETF NM+EF AF0 AF1 BE0 Table 11 - Mapping between MVTX2603AG and IETF Diffserv Classes for 10/100 Ports Features of the MVTX2603AG that correspond to the requirements of their associated IETF classes are summarized in the table below. Network management (NM) and Expedited forwarding (EF) • • • • Global buffer reservation for NM and EF Shaper for EF traffic on 1 Gbps ports Option of strict priority scheduling No dropping if admission controlled Assured forwarding (AF) • • • Four AF classes for 1 Gbps ports Programmable bandwidth partition, with option of WFQ service Option of delay-bounded service keeps delay under fixed levels even if not admission-controlled Random early discard, with programmable levels Global buffer reservation for each AF class • • Best effort (BE) • • • • Two BE classes for 1 Gbps ports Service only when other queues are idle means that QoS not adversely affected Random early discard, with programmable levels Traffic from flow control enabled ports automatically classified as BE Table 12 - MVTX2603AG Features Enabling IETF Diffserv Standards 32 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 8.0 Port Trunking 8.1 Features and Restrictions A port group (i.e. trunk) can include up to 4 physical ports, but all of the ports in a group must be in the same MVTX2603AG. The two Gigabit ports may also be trunked together. There are three trunk groups total, including the option to trunk Gigabit ports. Load distribution among the ports in a trunk for unicast is performed using hashing based on source MAC address and destination MAC address. Three other options include source MAC address only, destination MAC address only, and source port (in bidirectional ring mode only). Load distribution for multicast is performed similarly. If a VLAN includes any of the ports in a trunk group, all the ports in that trunk group should be in the same VLAN member map. The MVTX2603AG also provides a safe fail-over mode for port trunking automatically. If one of the ports in the trunking group goes down, the MVTX2603AG will automatically redistribute the traffic over to the remaining ports in the trunk. 8.2 Unicast Packet Forwarding The search engine finds the destination MCT entry, and if the status field says that the destination port found belongs to a trunk, then the group number is retrieved instead of the port number. In addition, if the source address belongs to a trunk, then the source port’s trunk membership register is checked. A hash key, based on some combination of the source and destination MAC addresses for the current packet, selects the appropriate forwarding port. 8.3 Multicast Packet Forwarding For multicast packet forwarding, the device must determine the proper set of ports from which to transmit the packet based on the VLAN index and hash key. Two functions are required in order to distribute multicast packets to the appropriate destination ports in a port trunking environment. Determining one forwarding port per group. For multicast packets, all but one port per group, the forwarding port, must be excluded. Preventing the multicast packet from looping back to the source trunk. The search engine needs to prevent a multicast packet from sending to a port that is in the same trunk group with the source port. This is because, when we select the primary forwarding port for each group, we do not take the source port into account. To prevent this, we simply apply one additional filter, so as to block that forwarding port for this multicast packet. Zarlink Semiconductor Inc. 33 MVTX2603 8.4 Data Sheet Trunking 3 trunk groups are supported. Groups 0 and 1 can trunk up to 4 10/100 ports. Group 2 can trunk 2 Gigabit ports. The supported combinations are shown in the following table. Group 0 Port 0 Port 1 Port 2 Port 3 X X X X X X X X X Port 4 Port 5 Port 6 Port 7 X X X X X X Select via trunk0_mode register Group 1 Select via trunk1_mode register Group 2 Port 25(Giga 0) Port 26 (Giga 1) X X The trunks are individually enabled/disabled by controlling pin trunk 0,1,2. 9.0 Port Mirroring 9.1 Port Mirroring Features The received or transmitted data of any 10/100 port in the MVTX2603AG chip can be “mirrored” to any other port. We support two such mirrored source-destination pairs. A mirror port cannot also serve as a data port. Please refer to the Port Mirroring Application note for further details. 9.2 • • • • 34 Setting Registers for Port Mirroring MIRROR1_SRC: Sets the source port for the first port mirroring pair. Bits [4:0] select the source port to be mirrored. An illegal port number is used to disable mirroring (which is the default setting). Bit [5] is used to select between ingress (Rx) or egress (Tx) data. MIRROR1_DEST: Sets the destination port for the first port mirroring pair. Bits [4:0] select the destination port to be mirrored. The default is port 23. MIRROR2_SRC: Sets the source port for the second port mirroring pair. Bits [4:0] select the source port to be mirrored. An illegal port number is used to disable mirroring (which is the default setting). Bit [5] is used to select between ingress (Rx) or egress (Tx) data. MIRROR2_DEST: Sets the destination port for the second port mirroring pair. Bits [4:0] select the destination port to be mirrored. The default is port 0. Zarlink Semiconductor Inc. MVTX2603 Data Sheet 10.0 TBI Interface The TBI interface can be used for 1000Mbps fiber operation. In this mode, the MVTX2604 is connected to the Serdes as shown in Figure 14. There are two TBI interfaces in the MVTX2604 devices. To enable to TBI function, the corresponding TXEN and TXER pins need to be boot strapped. See Ball – Signal Description for details. M25/26_TXD[9:0] T[9:0] M25/26_TXCLK REFCLK MVTX2603 SERDES M25/26_RXD[9:0] R[9:0] M25/26_RXCLK RBC0 M25/26_COL RBC1 Figure 14 - TBI Connection Zarlink Semiconductor Inc. 35 MVTX2603 Data Sheet 11.0 GPSI (7WS) Interface 11.1 11.1GPSI Connection The 10/100 RMII ethernet port can function in GPSI (7WS) mode when the corresponding TXEN pin is strapped low with a 1K pull down resistor. In this mode, the TXD[0], TXD[1], RXD[0] and RXD[1] serve as TX data, TX clock, RX data and RX clock respectively. The link status and collision from the PHY are multiplexed and shifted into the switch device through external glue logic. The duplex of the port can be controlled by programming the ECR register. The GPSI interface can be operated in port based VLAN mode only CRS_DV RXD[0] RXD[1] TXD[1] TXD[0] TXEN crs rxd rx_clk tx_clk link0 Port 0 Ethernet PHY col0 txd txen link1 260X link2 col2 SCAN_LINK SCAN_CLK SCAN_COL link23 col23 Port 23 Ethernet PHY Link Serializer (CPLD) Collision Serializer (CPLD) Figure 15 - GPSI (7WS) mode connection diagram 36 col1 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 11.2 SCAN LINK and SCAN COL interface An external CPLD logic is required to take the link signals and collision signals from the GPSI PHYs and shift them into the switch device. The switch device will drive out a signature to indicate the start of the sequence. After that, the CPLD should shift in the link and collision status of the PHYS as shown in the figure. The extra link status indicates the polarity of the link signal. One indicates the polarity of the link signal is active high. scan_clk scan_link/ scan_col 25 cycles for link/ 24 cycles for col Drived by VTX260x Driven by MVTX260x Drived by Driven byCPLD CPLD Total cycles period Total 32 32 cycles period Figure 16 - SCAN LINK and SCAN COLLISON status diagram 12.0 LED Interface 12.1 LED Interface Introduction A serial output channel provides port status information from the MVTX2603AG chips. It requires three additional pins: • • • A LED_CLK at 12.5 MHz LED_SYN a sync pulse that defines the boundary between status frames LED_DATA a continuous serial stream of data for all status LEDs that repeats once every frame time non-serial interface is also allowed, but in this case, only the Gigabit ports will have status LEDs. A low cost external device (44 pin PAL) is used to decode the serial data and to drive an LED array for display. This device can be customized for different needs. 12.2 Port Status In the MVTX2603AG, each port has 8 status indicators, each represented by a single bit. The 8 LED status indicators are • Bit 0: Flow control • Bit 1:Transmit data • Bit 2: Receive data • Bit 3: Activity (where activity includes either transmission or reception of data) • Bit 4: Link up • Bit 5: Speed (1= 100 Mb/s; 0= 10 Mb/s) • Bit 6: Full-duplex • Bit 7: Collision Eight clocks are required to cycle through the eight status bits for each port. Zarlink Semiconductor Inc. 37 MVTX2603 Data Sheet When the LED_SYN pulse is asserted, the LED interface will present 256 LED clock cycles with the clock cycles providing information for the following ports. Port 0 (10/100): cycles #0 to cycle #7 Port 1 (10/100): cycles#8 to cycle #15 Port 2 (10/100): cycle #16 to cycle #23 ... Port 22 (10/100): cycle #176 to cycle #183 Port 23 (10/100): cycle #184 to cycle #191 Port 24 (Gigabit 0): cycle #192 to cycle #199 Port 25 (Gigabit 1): cycle #200 to cycle #207 Byte 26 (additional status): cycle #208 to cycle #215 Byte 27 (additional status): cycle #216 to cycle #223 Cycles #224 to 256 present data with a value of zero. The first two bits of byte 26 provides the speed information for the Gigabit ports while the remainder of byte 26 and byte 27 provides bit status • • • • • • • • • • 26[0]: G0 port (1= port 24 is operating at Gigabit speed; 0= speed is either 10 or 100 Mb/s depending on speed bit of Port 24) 26[1]: G1 port (1= port 25 is operating at Gigabit speed; 0= speed is either 10 or 100 Mb/s depending on speed bit of Port 25) 26[2]: initialization done 26[3]: initialization start 26[4]: checksum ok 26[5]: link_init_complete 26[6]: bist_fail 26[7]: ram_error 27[0]: bist_in_process 27[1]: bist_done 12.3 LED Interface Timing Diagram The signal from the MVTX2603AG to the LED decoder is shown in Figure 17. Figure 17 - Timing Diagram of LED Interface 38 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.0 Register Definition 13.1 MVTX2603AG Register Description Register CPU Addr (Hex) Description R/W I2C Addr (Hex) Default Notes 0. ETHERNET Port Control Registers Substitute [N] with Port number (0..18) ECR1P”N” Port Control Register 1 for Port N 0000 + 2 x N R/W 000-018 020 ECR2P”N” Port Control Register 2 for Port N 001 + 2 x N R/W 01B-033 000 1. VLAN Control Registers Substitute [N] with Port number (0..1A) AVTCL VLAN Type Code Register Low 100 R/W 036 000 AVTCH VLAN Type Code Register High 101 R/W 037 081 PVMAP”N”_0 Port “N” Configuration Register 0 102 + 4N R/W 038-052 0FF PVMAP”N”_1 Port “N” Configuration Register 1 103 + 4N R/W 053-06D 0FF PVMAP”N”_2 Port “N” Configuration Register 2 104 + 4N R/W 06E-088 0FF PVMAP”N”_3 Port “N” Configuration Register 3 105 + 4N R/W 089-0A3 007 PVMODE VLAN Operating Mode 170 R/W 0A4 000 PVROUTE7-0 VLAN Router Group Enable 171-178 R/W NA 000 2. TRUNK Control Registers TRUNK0_L Trunk Group 0 Low 200 R/W NA 000 TRUNK0_M Trunk Group 0 Medium 201 R/W NA 000 TRUNK0_H Trunk Group 0 High 202 R/W NA 000 TRUNK0_ MODE Trunk Group 0 Mode 203 R/W 0A5 003 TRUNK0_ HASH0 Trunk Group 0 Hash 0 Destination Port 204 R/W NA 000 TRUNK0_ HASH1 Trunk Group 0 Hash 1 Destination Port 205 R/W NA 001 TRUNK0_ HASH2 Trunk Group 0 Hash 2 Destination Port 206 R/W NA 002 TRUNK0_ HASH3 Trunk Group 0 Hash 3 Destination Port 207 R/W NA 003 TRUNK1_L Trunk Group 1 Low 208 R/W NA 000 TRUNK1_M Trunk Group 1 Medium 209 R/W NA 000 TRUNK1_H Trunk Group 1 High 20A R/W NA 000 TRUNK1_ MODE Trunk Group 1 Mode 20B R/W 0A6 003 TRUNK1_ HASH0 Trunk Group 1 Hash 0 Destination Port 20C R/W NA 004 TRUNK1_ HASH1 Trunk Group 1 Hash 1 Destination Port 20D R/W NA 005 TRUNK1_ HASH2 Trunk Group 1 Hash 2 Destination Port 20E R/W NA 006 TRUNK1_ HASH3 Trunk Group 1 Hash 3 Destination Port 20F R/W NA 007 TRUNK2_ MODE Trunk Group 2 Mode 210 R/W NA 003 Zarlink Semiconductor Inc. 39 MVTX2603 Data Sheet Register CPU Addr (Hex) Description R/W I2C Addr (Hex) Default TRUNK2_ HASH0 Trunk Group 2 Hash 0 Destination Port 211 R/W NA 019 TRUNK2_ HASH1 Trunk Group 2 Hash 1 Destination Port 212 R/W NA 01A Multicast_ HASH0-0 Multicast hash result 0 mask byte 0 220 R/W NA 0FF Multicast_ HASH0-1 Multicast hash result 0 mask byte 1 221 R/W NA 0FF Multicast_ HASH0-2 Multicast hash result 0 mask byte 2 222 R/W NA 0FF Multicast_ HASH0-3 Multicast hash result 0 mask byte 3 223 R/W NA 0FF Multicast_ HASH1-0 Multicast hash result 1 mask byte 0 224 R/W NA 0FF Multicast_ HASH1-1 Multicast hash result 1 mask byte 1 225 R/W NA 0FF Multicast_ HASH1-2 Multicast hash result 1 mask byte 2 226 R/W NA 0FF Multicast_ HASH1-3 Multicast hash result 1 mask byte 3 227 R/W NA 0FF Multicast_ HASH2-0 Multicast hash result 2 mask byte 0 228 R/W NA 0FF Multicast_ HASH2-1 Multicast hash result 2 mask byte 1 229 R/W NA 0FF Multicast_ HASH2-2 Multicast hash result 2 mask byte 2 22A R/W NA 0FF Multicast_ HASH2-3 Multicast hash result 2 mask byte 3 22B R/W NA 0FF Multicast_ HASH3-0 Multicast hash result 3 mask byte 0 22C R/W NA 0FF Multicast_ HASH3-1 Multicast hash result 3 mask byte 1 22D R/W NA 0FF Multicast_ HASH3-2 Multicast hash result 3 mask byte 2 22E R/W NA 0FF Multicast_ HASH3-3 Multicast hash result 3 mask byte 3 22F R/W NA 0FF 3. CPU Port Configuration MAC0 CPU MAC Address byte 0 300 R/W NA 000 MAC1 CPU MAC Address byte 1 301 R/W NA 000 MAC2 CPU MAC Address byte 2 302 R/W NA 000 MAC3 CPU MAC Address byte 3 303 R/W NA 000 MAC4 CPU MAC Address byte 4 304 R/W NA 000 MAC5 CPU MAC Address byte 5 305 R/W NA 000 INT_MASK0 Interrupt Mask 0 306 R/W NA 000 INTP_MASK”N” Interrupt Mask for MAC Port 2N, 2N+1 310+N (310 -313) R/W NA 000 RQS Receive Queue Select 323 R/W NA 000 RQSS Receive Queue Status 324 RO NA N/A TX_AGE Transmission Queue Aging Time 325 R/W 0A7 008 400 R/W 0A8 2M:05C/ 4M:02E 4. Search Engine Configurations AGETIME_LOW 40 MAC Address Aging Time Low Zarlink Semiconductor Inc. Notes MVTX2603 Data Sheet Register CPU Addr (Hex) Description R/W I2C Addr (Hex) Default AGETIME_ HIGH MAC Address Aging Time High 401 R/W 0A9 000 V_AGETIME VLAN to Port Aging Time 402 R/W NA Off SE_OPMODE Search Engine Operating Mode 403 R/W NA 000 SCAN Scan control register 404 R/W NA 000 Notes 5. Buffer Control and QOS Control FCBAT FCB Aging Timer 500 R/W 0AA 0FF QOSC QOS Control 501 R/W 0AB 000 FCR Flooding Control Register 502 R/W 0AC 008 AVPML VLAN Priority Map Low 503 R/W 0AD 000 AVPMM VLAN Priority Map Middle 504 R/W 0AE 000 AVPMH VLAN Priority Map High 505 R/W 0AF 000 TOSPML TOS Priority Map Low 506 R/W 0B0 000 TOSPMM TOS Priority Map Middle 507 R/W 0B1 000 TOSPMH TOS Priority Map High 508 R/W 0B2 000 AVDM VLAN Discard Map 509 R/W 0B3 000 TOSDML TOS Discard Map 50A R/W 0B4 000 BMRC Broadcast/Multicast Rate Control 50B R/W 0B5 000 UCC Unicast Congestion Control 50C R/W 0B6 2M:008/ 4M:010 MCC Multicast Congestion Control 50D R/W 0B7 050 PR100 Port Reservation for 10/100 Ports 50E R/W 0B8 2M:024/ 4M:036 SFCB Share FCB Size 510 R/W 0BA 2M:014/ 4M:064 C2RS Class 2 Reserve Size 511 R/W 0BB 000 C3RS Class 3 Reserve Size 512 R/W 0BC 000 C4RS Class 4 Reserve Size 513 R/W 0BD 000 C5RS Class 5 Reserve Size 514 R/W 0BE 000 C6RS Class 6 Reserve Size 515 R/W 0BF 000 C7RS Class 7 Reserve Size 516 R/W 0C0 000 QOSC”N” QOS Control (N=0 - 5) 517- 51C R/W 0C1-0C6 000 QOS Control (N=6 - 11) 51D- 522 R/W NA 000 QOS Control (N=12 - 23) 523- 52E R/W 0C7-0D2 000 QOS Control (N=24 - 59) 52F- 552 R/W NA 000 Zarlink Semiconductor Inc. 41 MVTX2603 Data Sheet Register CPU Addr (Hex) Description R/W I2C Addr (Hex) Default QOSC”N” QOS Control (N=0 59) 517 512 R/W 0C1-0D2 000 RDRC0 WRED Drop Rate Control 0 553 R/W 0FB 08F RDRC1 WRED Drop Rate Control 1 554 R/W 0FC 088 USER_ PORT”N”_LOW User Define Logical Port “N” Low (N=0-7) 580 + 2N R/W 0D6-0DD 000 USER_ PORT”N”_HIGH User Define Logical Port “N” High 581 + 2N R/W 0DE-0E5 000 USER_ PORT1:0_ PRIORITY User Define Logic Port 1 and 0 Priority 590 R/W 0E6 000 USER_ PORT3:2_ PRIORITY User Define Logic Port 3 and 2 Priority 591 R/W 0E7 000 USER_ PORT5:4_ PRIORITY User Define Logic Port 5 and 4 Priority 592 R/W 0E8 000 USER_ PORT7:6_PRI ORITY User Define Logic Port 7 and 6 Priority 593 R/W 0E9 000 USER_PORT_ ENABLE User Define Logic Port Enable 594 R/W 0EA 000 WLPP10 Well known Logic Port Priority for 1 and 0 595 R/W 0EB 000 WLPP32 Well known Logic Port Priority for 3 and 2 596 R/W 0EC 000 WLPP54 Well known Logic Port Priority for 5 and 4 597 R/W 0ED 000 WLPP76 Well-known Logic Port Priority for 7 & 6 598 R/W 0EE 000 WLPE Well known Logic Port Enable 599 R/W 0EF 000 RLOWL User Define Range Low Bit7:0 59A R/W 0F4 000 RLOWH User Define Range Low Bit 15:8 59B R/W 0F5 000 RHIGHL User Define Range High Bit 7:0 59C R/W 0D3 000 RHIGHH User Define Range High Bit 15:8 59D R/W 0D4 000 RPRIORITY User Define Range Priority 59E R/W 0D5 000 CPUQOSC1~3 Byte limit for TxQ on CPU port 5A0-5A2 R/W NA 000 6. MISC Configuration Registers MII_OP0 MII Register Option 0 600 R/W 0F0 000 MII_OP1 MII Register Option 1 601 R/W 0F1 000 FEN Feature Registers 602 R/W 0F2 010 MIIC0 MII Command Register 0 603 R/W N/A 000 MIIC1 MII Command Register 1 604 R/W N/A 000 42 Zarlink Semiconductor Inc. Notes MVTX2603 Data Sheet Register CPU Addr (Hex) Description R/W I2C Addr (Hex) Default MIIC2 MII Command Register 2 605 R/W N/A 000 MIIC3 MII Command Register 3 606 R/W N/A 000 MIID0 MII Data Register 0 607 RO N/A N/A MIID1 MII Data Register 1 608 RO N/A N/A LED LED Control Register 609 R/W 0F3 000 DEVICE Device id and test 60A R/W N/A 000 SUM EEPROM Checksum Register 60B R/W 0FF 000 Notes 7. Port Mirroring Controls MIRROR1_SRC Port Mirror 1 Source Port 700 R/W N/A 07F MIRROR1_ DEST Port Mirror 1 Destination Port 701 R/W N/A 017 MIRROR2_SRC Port Mirror 2 Source Port 702 R/W N/A 0FF MIRROR2_ DEST Port Mirror 2 Destination Port 703 R/W N/A 000 F. Device Configuration Register GCR Global Control Register F00 R/W N/A 000 DCR Device Status and Signature Register F01 RO N/A N/A DCR1 Giga Port status F02 RO N/A N/A DPST Device Port Status Register F03 R/W N/A 000 DTST Data read back register F04 RO N/A N/A DA DA Register FFF RO N/A DA 13.2 Group 0 Address MAC Ports Group 13.2.1 ECR1Pn: Port N Control Register • • I2C Address h000-01A; CPU Address: 0000+2xN Accessed by serial interface and I2C (R/W) 7 6 Sp State 5 A-FC 4 3 2 1 0 Port Mode Zarlink Semiconductor Inc. 43 MVTX2603 Data Sheet Bit [0] • • 1 - Flow Control Off 0 - Flow Control On • When Flow Control On: • In half duplex mode, the MAC transmitter applies back pressure for flow control. • In full duplex mode, the MAC transmitter sends Flow Control frames when necessary. The MAC receiver interprets and processes incoming flow control frames. The Flow Control Frame Received counter is incremented whenever a flow control is received. • When Flow Control off: • In half duplex mode, the MAC Transmitter does not assert flow control by sending flow control frames or jamming collision. • In full duplex mode, the Mac transmitter does not send flow control frames. The MAC receiver does not interpret or process the flow control frames. The Flow Control Frame Received counter is not incremented. Bit [1] • • 1 - Half Duplex - Only 10/100 mode 0 - Full Duplex Bit [2] • • 1 - 10Mbps 0 - 100Mbps Bit [4:3] • • 00 - Automatic Enable Auto Neg. This enables hardware state machine for auto-negotiation. 01 - Limited Disable auto Neg. This disables hardware for speed autonegotiation. Poll MII for link status. 10 - Link Down. Disable auto Neg. state machine and force link down (disable the port) 11 - Link Up. User ERC1 [2:0] for config. • Asymmetric Flow Control Enable • • Bit [5] • 0 - Disable asymmetric flow control • 1 - Enable asymmetric flow control Bit [7:6] • Asymmetric Flow Control Enable. When this bit is set and flow control is on (bit[0] = 0, don't send out a flow control frame. But MAC receiver interprets and process flow control frames. Default is 0 • SS - Spanning tree state Default is 11 • • • • 13.2.2 • • 00 – Blocking: Frame is dropped 01 - Listening: Frame is dropped 10 - Learning: Frame is dropped. Source MAC address is learned. 11 - Forwarding: Frame is forwarded. Source MAC address is learned. ECR2Pn: Port N Control Register I2C Address: h01B-035; CPU Address: h0001+2xN Accessed by and serial interface and I2C (R/W) 7 6 5 4 QoS Sel 44 Reserve 2 1 0 DisL Ftf Futf Zarlink Semiconductor Inc. MVTX2603 Data Sheet Bit[0]: • Filter untagged frame (Default 0) • 0: Disable • 1: All untagged frames from this port are discarded Bit[1]: • Filter Tag frame (Default 0) • 0: Disable • 1: All tagged frames from this port are discarded Bit[2]: • Learning Disable (Default 0) • 1 Learning is disabled on this port • 0 Learning is enabled on this port Bit[3]: • Must be set to ‘1’ Bit [5:4:] • • • QOS mode selection (Default 00) Determines which of the 4 sets of QoS settings is used for 10/100 ports. Note that there are 4 sets of per-queue byte thresholds, and 4 sets of WFQ ratios programmed. These bits select among the 4 choices for each 10/100 port. Refer to QoS Application Note. • • • • Bit[7:6] 13.2.3 • • • 00: select class byte limit set 0 and classes WFQ credit set 0 01: select class byte limit set 1 and classes WFQ credit set 1 10: select class byte limit set 2 and classes WFQ credit set 2 11: select class byte limit set 3 and classes WFQ credit set 3 Reserved GGControl – Extra GIGA Port Control CPU Address: h036 Accessed by serial interface (R/W) 7 6 5 4 3 DF DI MiiB RstA DF Bit[0]: • 2 1 0 MiiA RstA Reset GIGA port A • 0: Normal operation (default) • 1: Reset Gigabit port A Bit[1]: • GIGA port A use MII interface (10/100M) • 0: Gigabit port operations at 1000 mode • 1: Gigabit port operations at 10/100 mode Bit[2]: • Reserved - Must be zero Bit[3]: • GIGA port A direct flow control (MAC to MAC connection). The MVTX2603AG supports direct flow control mechanism, the flow control frame is therefore not sent through the Gigabit port data path. • 0: Direct flow control disabled (default) • 1: Direct flow control enabled Bit[4]: • Reset GIGA port B • 0: Normal operation (default) • 1: Reset Gigabit port B Zarlink Semiconductor Inc. 45 MVTX2603 Bit[5]: Data Sheet • GIGA port B use MII interface (10/100M) • 0: Gigabit port operates at 1000 mode • 1: Gigabit port operates at 10/100 mode Bit[6]: • Device information attach enable for Gigabit port B • 0: Disable preamble stack device ID insertion (default) • 1: Insert stack device ID into the preamble (must be enabled for ring mode). Bit[7]: • GIGA port B direct flow control (MAC to MAC connection). The MVTX2603AG supports direct flow control mechanism, the flow control frame is therefore not sent through the Gigabit port data path. • 0: Direct flow control disabled (default) • 1: Direct flow control enabled 13.3 Group 1 Address VLAN Group 13.3.1 AVTCL – VLAN Type Code Register Low • • I 2C Address h036; CPU Address: h100 Accessed by serial interface and I2C (R/W) Bit[7:0]: 13.3.2 • • VLANType_LOW: Lower 8 bits of the VLAN type code (Default 00) AVTCH – VLAN Type Code Register High I 2C Address h037; CPU Address: h101 Accessed by serial interface and I2C (R/W) Bit[7:0]: 13.3.3 • • • • VLANType_HIGH: Upper 8 bits of the VLAN type code (Default is 81) PVMAP00_0 – Port 00 Configuration Register 0 I2C Address h038, CPU Address: h102 Accessed by serial interface and I2C (R/W) Bit[7:0]: • VLAN Mask for ports 7 to 0 (Default FF) This register indicates the legal egress ports. A “1” on bit 7 means that the packet can be sent to port 7. A “0” on bit 7 means that any packet destined to port 7 will be discarded. This register works with registers 1, 2 and 3 to form a 27 bit mask to all egress ports. 13.3.4 • • PVMAP00_1 – Port 00 Configuration Register 1 I2C Address h39, CPU Address: h103 Accessed by serial interface and I2C (R/W) Bit[7:0]: 13.3.5 • • 46 • VLAN Mask for ports 15 to 8 (Default is FF) PVMAP00_2 – Port 00 Configuration Register 2 I2C Address h3A, CPU Address: h104 Accessed by serial interface and I2C (R/W) Zarlink Semiconductor Inc. MVTX2603 Data Sheet Bit [7:0]: 13.3.6 • • VLAN Mask for ports 23 to 16 (Default FF) PVMAP00_3 – Port 00 Configuration Register 3 I 2C Address h3b, CPU Address: h105 Accessed by serial interface and I2C (R/W) 13.4 • • • • • • • • • • • • • • • 7 6 FP en Drop 5 3 Default tx priority 2 0 VLAN Mask Bit [2:0]: VLAN Mask for ports 26 to 24 (Default 7) (Port 24 is not used) Bit [5:3]: Default Transmit priority. Used when Bit[7] = 1 (Default 0) • 000 Transmit Priority Level 0 (Lowest) • 001 Transmit Priority Level 1 • 010 Transmit Priority Level 2 • 011 Transmit Priority Level 3 • 100 Transmit Priority Level 4 • 101 Transmit Priority Level 5 • 110 Transmit Priority Level 6 • 111 Transmit Priority Level 7 (Highest) Bit [6]: Default Discard priority (Default 0) • 0 - Discard Priority Level 0 (Lowest) • 1 - Discard Priority Level 7(Highest) Bit [7]: Enable Fix Priority (Default 0) • 0 Disable fix priority. All frames are analysed. Transmit Priority and Discard Priority are based on VLAN Tag, TOS field or Logical Port. • 1 Transmit Priority and Discard Priority are based on values programmed in bit [6:3] Port Configuration Register PVMAP01_0,1,2,3 I2C Address h3C,3D,3E,3F; CPU Address:h106,107,108,109) PVMAP02_0,1,2,3 I2C Address h40,41,42,43; CPU Address:h10A, 10B, 10C, 10D) PVMAP03_0,1,2,3 I2C Address h44,45,46,47; CPU Address:h10E, 10F, 110, 111) PVMAP04_0,1,2,3 I2C Address h48,49,4A,4B; CPU Address:h112, 113, 114, 115) PVMAP05_0,1,2,3 I2C Address h4C,4D,4E,4F; CPU Address:h116, 117, 118, 119) PVMAP06_0,1,2,3 I2C Address h50,51,52,53; CPU Address:h11A, 11B, 11C, 11D) PVMAP07_0,1,2,3 I2C Address h54,55,56,57; CPU Address:h11E, 11F, 120, 121) PVMAP08_0,1,2,3 I2C Address h58,59,5A,5B; CPU Address:h122, 123, 124, 125) PVMAP09_0,1,2,3 I2C Address h5C,5D,5E,5F; CPU Address:h126, 127, 128, 129) PVMAP10_0,1,2,3 I2C Address h60,61,62,63; CPU Address:h12A, 12B, 12C, 12D) PVMAP11_0,1,2,3 I2C Address h64,65,66,67; CPU Address:h12E, 12F, 130, 131) PVMAP12_0,1,2,3 I2C Address h68,69,6A,6B; CPU Address:h132, 133, 134, 135) PVMAP13_0,1,2,3 I2C Address h6C,6D,6E,6F; CPU Address:h136, 137, 138, 139) PVMAP14_0,1,2,3 I2C Address h70,71,72,73; CPU Address:h13A, h13B, 13C, 13D) Zarlink Semiconductor Inc. 47 MVTX2603 • • • • • • • • • • • • PVMAP15_0,1,2,3 PVMAP16_0,1,2,3 PVMAP17_0,1,2,3 PVMAP18_0,1,2,3 PVMAP19_0,1,2,3 PVMAP20_0,1,2,3 PVMAP21_0,1,2,3 PVMAP22_0,1,2,3 PVMAP23_0,1,2,3 PVMAP24_0,1,2,3 PVMAP25_0,1,2,3 PVMAP26_0,1,2,3 13.4.1 • • Data Sheet I 2C I 2C I 2C I 2C I 2C I 2C I 2C I 2C I 2C I 2C I 2C I 2C Address Address Address Address Address Address Address Address Address Address Address Address h74,75,76,77; CPU Address:h13E, 13F, 140, 141) h78,79,7A,7B; CPU Address:h142, 143, 144, 145) h7C,7D,7E,7F; CPU Address:h146, 147, 148, 149) h80,81,82,83; CPU Address:h14A, 14B, 14C, 14D) h84,85,86,87; CPU Address:h14E, 14F, 150, 151) h88,89,8A,8B; CPU Address:h152, 153, 154, 155) h8C,8D,8E,8F; CPU Address:h156, 157, 158, 159) h90,91,92,93; CPU Address:h15A, 15B, 15C, 15D) h94,95,96,97; CPU Address:h15E, 15F, 160, 161) h98,99,9A,9B; CPU Address:h162, 163, 164, 165) (Not used) h9C,9D,9E,9F; CPU Address:h166, 167, 168, 169) (Gigabit port 1) hA0,A1,A2,A3; CPU Address:h16A, 16B, 16C, 16D) (Gigabit port 2) PVMODE I2C Address: h0A4, CPU Address: h170 Accessed by serial interface, and I2C (R/W) 7 0 DF SL Bit [0]: • • Reserved Must be ‘0’ Bit [1]: • Slow learning Same function as SE_OP MODE bit 7. Either bit can enable the function; both need to be turned off to disable the feature. Bit [2]: • Disable dropping frames with destination MAC addresses 0180C2000001 to 0180C200000F • 0: Drop all frames in the range • 1: Treats frames as multicast Bit [3]: • 1: Disable reset PCS • 0: Enable reset PCS. PCS FIFO will be reset when receiving a PCS symbol error. Bit [4]: • Support MAC address 0 • 0: MAC address 0 is not learned. • 1: MAC address 0 is learned. Bit [7:5]: 13.4.2 • • • Reserved TRUNK0_MODE– Trunk group 0 mode I 2C Address: h0A5; CPU Address: h203 Accessed by serial interface and I2C (R/W) 7 3 2 Hash Select 48 Zarlink Semiconductor Inc. 1 0 Port Select MVTX2603 Data Sheet Bit [1:0]: • Port selection in unmanaged mode. Input pin TRUNK0 enable/disable trunk group 0. • • • • Bit [3:2] • 00 Reserved 01 Port 0 and 1 are used for trunk 0 10 Port 0,1 and 2 are used for trunk 0 11 Port 0,1,2 and 3 are used for trunk 0 Hash Select. The Hash selected is valid for Trunk 0, 1 and 2. (Default 00) • • • • 00 Use Source and Destination Mac Address for hashing 01 Use Source Mac Address for hashing 10 Use Destination Mac Address for hashing 11 Use source destination MAC address and ingress physical port number for hashing Note: Trunk group 2 (two gigabit ports) is enabled/disabled using input pin TRUNK2. 13.4.3 • • TRUNK1_MODE – Trunk group 1 mode I2C Address: h0A6; CPU Address: h20B Accessed by serial interface and I2C (R/W) 7 3 2 1 0 Port Select Bit [1:0]: • • • • • 13.4.4 • • • TRUNK1_HASH0 – Trunk group 1 hash result 0 destination port number CPU Address: h20C Accessed by serial interface (R/W) Bit [4:0] Hash result 0 destination port number (Default 04) 13.4.5 • • Port selection in unmanaged mode. Input pin TRUNK1 enable/disable trunk group 1. 00 Reserved 01 Port 4 and 5 are used for trunk1 10 Reserved 11 Port 4,5,6 and 7 are used for trunk1 TX_AGE – Tx Queue Aging timer I 2C Address: h07;CPU Address: h325 Accessed by serial interface (RW) 7 5 0 Tx Queue Agent • • • Bit[5:0]: Unit of 100ms (Default 8) Disable transmission queue aging if value is zero. Aging timer for all ports and queues. For no packet loss flow control, this register must be set to 0. 13.5 Group 4 Address Search Engine Group 13.5.1 AGETIME_LOW – MAC address aging time Low Zarlink Semiconductor Inc. 49 MVTX2603 • • • • I2C Address: h0A8; CPU Address: h400 Accessed by serial interface and I2C (R/W) Bit [7:0] Low byte of the MAC address aging timer. MAC address aging is enable/disable by boot strap TSTOUT9 13.5.2 • • • • • 50 Data Sheet AGETIME_HIGH –MAC address aging time High I 2C Address: h0A9; CPU Address: h401 Accessed by serial interface and I2C (R/W) Bit [7:0]: High byte of the MAC address aging timer. The default setting provide 300 seconds aging time. Aging time is based on the following equation: {AGETIME_TIME,AGETIME_LOW} X (# of MAC address entries in the memory x 100µsec). Number of MAC entries = 32K when 1MB is used per bank. Number of MAC entries = 64K when 2MB is used per bank. Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.5.3 • • • CPU Address: h402 Accessed by serial interface (R/W) Bit [7:0] (Default FF) Reserved 13.5.4 • • • V_AGETIME – VLAN to Port aging time SE_OPMODE – Search Engine Operation Mode CPU Address: h403 Accessed by serial interface (R/W) {SE_OPMODE} X(# of entries 100usec) 7 6 5 SL DMS 4 3 Bit [0]: • Reserved Bit [1]: • Reserved Bit [2]: • Reserved Bit [3]: • Reserved Bit [4]: • Reserved Bit [5]: • Reserved Bit [6]: • Disable MCT speedup aging 2 1 0 • 1 – Disable speedup aging when MCT resource is low. • 0 – Enable speedup aging when MCT resource is low. Bit [7]: • Slow Learning • 1– Enable slow learning. Learning is temporary disabled when search demand is high • 0 – Learning is performed independent of search demand 13.6 Group 5 Address Buffer Control/QOS Group 13.6.1 FCBAT – FCB Aging Timer • I 2C Address: h0AA; CPU Address: h500 7 0 FCBAT Bit [7:0]: 13.6.2 • • • • FCB Aging time. Unit of 1ms. (Default FF) This function is for buffer aging control. It is used to configure the aging time, and can be enabled/ disabled through bootstrap pin. It is not recommended to use this function for normal operation. QOSC – QOS Control I2C Address: h0AB; CPU Address: h501 Accessed by serial interface and I2C (R/W) Zarlink Semiconductor Inc. 51 MVTX2603 Data Sheet 7 6 Tos-d Tos-p 5 4 0 VF1c L Bit [0]: • QoS frame lost is OK. Priority will be available for flow control enabled source only when this bit is set (Default 0) Bit [4]: • Per VLAN Multicast Flow Control (Default 0) • 0 - Disable • 1 - Enable Bit [5]: • Reserved Bit [6]: • Select TOS bits for Priority (Default 0) • 0 - Use TOS [4:2] bits to map the transmit priority • 1 - Use TOS [7:5] bits to map the transmit priority Bit [7]: • Select TOS bits for Drop Priority (Default 0) • 0 - Use TOS[4:2] bits to map the drop priority • 1 - Use TOS[7:5] bits to map the drop priority 13.6.3 • • FCR – Flooding Control Register I2C Address: h0AC; CPU Address: h502 Accessed by serial interface and I2C (R/W) 7 6 Tos 4 3 TimeBase U2MR Bit [3:0]: • U2MR: Unicast to Multicast Rate. Units in terms of time base defined in bits [6:4]. This is used to limit the amount of flooding traffic. The value in U2MR specifies how many packets are allowed to flood within the time specified by bit [6:4]. To disable this function, program U2MR to 0. (Default = 8) Bit [6:4]: • TimeBase: 000 = 100us 001 = 200us 010 = 400us 011 = 800us 100 = 1.6ms 101 = 3.2ms 110 = 6.4ms 111 = 100us (same as 000) • 52 0 (Default = 000) Zarlink Semiconductor Inc. MVTX2603 Data Sheet Bit [7]: • Select VLAN tag or TOS (IP packets) to be preferentially picked to map transmit priority and drop priority (Default = 0). • 0 – Select VLAN Tag priority field over TOS • 1 – Select TOS over VLAN tag priority field 13.6.4 • • AVPML – VLAN Priority Map I 2C Address: h0AD; CPU Address: h503 Accessed by serial interface and I2C (R/W) 7 6 5 3 2 0 Registers AVPML, AVPMM, and AVPMH allow the eight VLAN priorities to map into eight internal level transmit priorities. Under the internal transmit priority, seven is highest priority where as zero is the lowest. This feature allows the user the flexibility of redefining the VLAN priority field. For example, programming a value of 7 into bit 2:0 of the AVPML register would map VLAN priority 0 into internal transmit priority 7. The new priority is used inside the 2603. When the packet goes out it carries the original priority. 13.6.5 • • Bit [2:0]: • Priority when the VLAN tag priority field is 0 (Default 0) Bit [5:3]: • Priority when the VLAN tag priority field is 1 (Default 0) Bit [7:6]: • Priority when the VLAN tag priority field is 2 (Default 0) AVPMM – VLAN Priority Map I2C Address: h0AE, CPU Address: h504 Accessed by serial interface and I2C (R/W) 7 • 4 3 1 0 Map VLAN priority into eight level transmit priorities: 13.6.6 • • 6 Bit [0]: • Priority when the VLAN tag priority field is 2 (Default 0) Bit [3:1]: • Priority when the VLAN tag priority field is 3 (Default 0) Bit [6:4]: • Priority when the VLAN tag priority field is 4 (Default 0) Bit [7]: • Priority when the VLAN tag priority field is 5 (Default 0) AVPMH – VLAN Priority Map I 2C Address: h0AF, CPU Address: h505 Accessed by serial interface and I2C (R/W) 7 6 4 3 1 0 Map VLAN priority into eight level transmit priorities: Bit [1:0]: • Priority when the VLAN tag priority field is 5 (Default 0) Zarlink Semiconductor Inc. 53 MVTX2603 54 Data Sheet Bit [4:2]: • Priority when the VLAN tag priority field is 6 (Default 0) Bit [7:5]: • Priority when the VLAN tag priority field is 7 (Default 0) Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.6.7 • • TOSPML – TOS Priority Map I2C Address: h0B0, CPU Address: h506 Accessed by serial interface and I2C (R/W) 7 0 Map TOS field in IP packet into eight level transmit priorities 13.6.8 • • Bit [2:0]: • Priority when the TOS field is 0 (Default 0) Bit [5:3]: • Priority when the TOS field is 1 (Default 0) Bit [7:6]: Priority when the TOS field is 2 (Default 0) TOSPMM – TOS Priority Map I2C Address: h0B1, CPU Address: h507 Accessed by serial interface and I2C (R/W) 7 0 Map TOS field in IP packet into four level transmit priorities 13.6.9 • • Bit [0]: • Priority when the TOS field is 2 (Default 0) Bit [3:1]: • Priority when the TOS field is 3 (Default 0) Bit [6:4]: • Priority when the TOS field is 4 (Default 0) Bit [7]: • Priority when the TOS field is 5 (Default 0) TOSPMH – TOS Priority Map I 2C Address: h0B2, CPU Address: h508 Accessed by serial interface and I2C (R/W) 7 0 Map TOS field in IP packet into four level transmit priorities: Bit [1:0]: • Priority when the TOS field is 5 (Default 0) Bit [4:2]: • Priority when the TOS field is 6 (Default 0) Bit [7:5]: • Priority when the TOS field is 7 (Default 0) Zarlink Semiconductor Inc. 55 MVTX2603 Data Sheet 13.6.10 AVDM – VLAN Discard Map • • I2C Address: h0B3, CPU Address: h509 Accessed by serial interface and I2C (R/W) 7 0 Map VLAN priority into frame discard when low priority buffer usage is above threshold Bit [0]: • Frame drop priority when VLAN tag priority field is 0 (Default 0) Bit [1]: • Frame drop priority when VLAN tag priority field is 1 (Default 0) Bit [2]: • Frame drop priority when VLAN tag priority field is 2 (Default 0) Bit [3]: • Frame drop priority when VLAN tag priority field is 3 (Default 0) Bit [4]: • Frame drop priority when VLAN tag priority field is 4 (Default 0) Bit [5]: • Frame drop priority when VLAN tag priority field is 5 (Default 0) Bit [6]: • Frame drop priority when VLAN tag priority field is 6 (Default 0) Bit [7]: • Frame drop priority when VLAN tag priority field is 7 (Default 0) 13.6.11 TOSDML – TOS Discard Map • • I2C Address: h0B4, CPU Address: h50A Accessed by serial interface and I2C (R/W) 7 0 Map TOS into frame discard when low priority buffer usage is above threshold 56 Bit [0]: • Frame drop priority when TOS field is 0 (Default 0) Bit [1]: • Frame drop priority when TOS field is 1 (Default 0) Bit [2]: • Frame drop priority when TOS field is 2 (Default 0) Bit [3]: • Frame drop priority when TOS field is 3 (Default 0) Bit [4]: • Frame drop priority when TOS field is 4 (Default 0) Bit [5]: • Frame drop priority when TOS field is 5 (Default 0) Bit [6]: • Frame drop priority when TOS field is 6 (Default 0) Bit [7]: • Frame drop priority when TOS field is 7 (Default 0) Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.6.12 BMRC - Broadcast/Multicast Rate Control • • I2C Address: h0B5, CPU Address: h50B Accessed by serial interface and I2C (R/W) 7 0 Broadcast Rate • Multicast Rate This broadcast and multicast rate defines for each port the number of packet allowed to be forwarded within a specified time. Once the packet rate is reached, packets will be dropped. To turn off the rate limit, program the field to 0. Timebase is based on register 502 [6:4]. Bit [3:0]: • Multicast Rate Control Number of multicast packets allowed within the time defined in bits 6 to 4 of the Flooding Control Register (FCR). (Default 0). Bit [7:4]: • Broadcast Rate Control Number of broadcast packets allowed within the time defined in bits 6 to 4 of the Flooding Control Register (FCR). (Default 0) 13.6.13 UCC – Unicast Congestion Control • • I2C Address: h0B6, CPU Address: h50C Accessed by serial interface and I2C (R/W) 7 0 Unicast congest threshold Bit [7:0]: • Number of frame count. Used for best effort dropping at B% when destination port’s best effort queue reaches UCC threshold and shared pool is all in use. Granularity 1 frame. (Default: h10 for 2 MB/bank or h08 for 1 MB/bank) 13.6.14 MCC – Multicast Congestion Control • • I2C Address: h0B7, CPU Address: h50D Accessed by serial interface and I2C (R/W) 7 5 FC reaction prd 4 0 Multicast congest threshold Bit [4:0]: • In multiples of two. Used for triggering MC flow control when destination multicast port’s best effort queue reaches MCC threshold. (Default 0x10) Bit [7:5]: • Flow control reaction period (Default 2) Granularity 4uSec. Zarlink Semiconductor Inc. 57 MVTX2603 Data Sheet 13.6.15 PR100 – Port Reservation for 10/100 ports • • I2C Address: h0B8, CPU Address: h50E Accessed by serial interface and I2C (R/W) 7 4 3 Buffer low thd 0 SP Buffer reservation Bit [3:0]: • • Per port buffer reservation. Define the space in the FDB reserved for each 10/100 port. Expressed in multiples of 4 packets. For each packet 1536 bytes are reserved in the memory. Bits [7:4]: • Expressed in multiples of 4 packets. Threshold for dropping all best effort frames when destination port best efforts queues reach UCC threshold and shared pool all used and source port reservation is at or below the PR100[7:4] level. Also the threshold for initiating UC flow control. Default: • • h36 for 24+2 configuration with memory 2MB/bank; • h24 for 24+2 configuration with 1MB/bank; 13.6.16 PRG – Port Reservation for Giga ports • • I2C Address: h0B9, CPU Address: h50F Accessed by serial interface and I2C (R/W) 7 3 Buffer low thd SP buffer reservation Bit [3:0]: • • Per source port buffer reservation. Define the space in the FDB reserved for each Gigabit port. Expressed in multiples of 16 packets. For each packet 1536 bytes are reserved in the memory. Bits [7:4]: • Expressed in multiples of 16 packets. Threshold for dropping all best effort frames when destination port best effort queues reach UCC threshold and shared pool is all used and source port reservation is at or below the PRG[7:4] level. Also the threshold for initiating UC flow control. Default: • • H58 for memory 2MB/bank; • H35 for 1MB/bank; 58 0 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.6.17 SFCB – Share FCB Size • • I2C Address: h0BA, CPU Address: h510 Accessed by serial interface and I2C (R/W) 7 0 Shared buffer size Bits [7:0]: • • Expressed in multiples of 4 packets. Buffer reservation for shared pool. Default: • h64 for 24+2 configuration with memory of 2MB/bank; • h14 for 24+2 configuration with memory of 1MB/bank; 13.6.18 C2RS – Class 2 Reserve Size • • I2C Address: h0BB, CPU Address: h511 Accessed by serial interface and I2C (R/W) 7 0 Class 2 FCB Reservation • Buffer reservation for class 2 (third lowest priority). Granularity 1. (Default 0) 13.6.19 C3RS – Class 3 Reserve Size • • I2C Address: h0BC, CPU Address: h512 Accessed by serial interface and I2C (R/W) 7 0 Class 3 FCB Reservation • Buffer reservation for class 3. Granularity 1. (Default 0) 13.6.20 C4RS – Class 4 Reserve Size • • I2C Address: h0BD, CPU Address: h513 Accessed by serial interface and I2C (R/W) 7 0 Class 4 FCB Reservation • Buffer reservation for class 4. Granularity 1. (Default 0) 13.6.21 C5RS – Class 5 Reserve Size • • I2C Address: h0BE; CPU Address: h514 Accessed by serial interface and I2C (R/W) 7 0 Class 5 FCB Reservation • Buffer reservation for class 5. Granularity 1. (Default 0) Zarlink Semiconductor Inc. 59 MVTX2603 Data Sheet 13.6.22 C6RS – Class 6 Reserve Size • • I2C Address: h0BF; CPU Address h515 Accessed by serial interface and I2C (R/W) 7 0 Class 6 FCB Reservation • Buffer reservation for class 6 (second highest priority). Granularity 1. (Default 0) 13.6.23 C7RS – Class 7 Reserve Size • • I2C Address: h0C0; CPU Address: h516 Accessed by serial interface and I2C (R/W) 7 0 Class 7 FCB Reservation • Buffer reservation for class 7 (highest priority). Granularity 1. (Default 0) 13.6.24 Classes Byte Limit Set 0 • • • • Accessed by serial interface and I2C (R/W) C — QOSC00 – BYTE_C01 (I2C Address h0C1, CPU Address 517) B — QOSC01 – BYTE_C02 (I2C Address h0C2, CPU Address 518) A — QOSC02 – BYTE_C03 (I2C Address h0C3, CPU Address 519) QOSC00 through QOSC02 represents one set of values A-C for a 10/100 port when using the Weighted Random Early Drop (WRED) Scheme described in Chapter 7.7. There are four such sets of values A-C specified in Classes Byte Limit Set 0, 1, 2, and 3. Each 10/ 100 port can choose one of the four Byte Limit Sets as specified by the QoS Select field located in bits 5 to 4 of the ECR2n register. The values A-C are per-queue byte thresholds for random early drop. QOSC02 represents A, and QOSC00 represents C. Granularity when Delay bound is used: QOSC02: 128 bytes, QOSC01: 256 bytes. QOSC00: 512 bytes. Granularity when WFQ is used: QOSC02: 512 bytes, QOSC01: 512 bytes, QOSC00: 512 bytes. 13.6.25 Classes Byte Limit Set 1 • Accessed by serial interface and I2C (R/W) C - QOSC03 – BYTE_C11 (I2C Address h0C4, CPU Address 51a) B - QOSC04 – BYTE_C12 (I2C Address h0C5, CPU Address 51b) A - QOSC05 – BYTE_C13 (I2C Address h0C6, CPU Address 51c) QOSC03 through QOSC05 represents one set of values A-C for a 10/100 port when using the Weighted Random Early Detect (WRED) Scheme. Granularity when Delay bound is used: QOSC05: 128 bytes, QOSC04: 256 bytes. QOSC03: 512 bytes. Granularity when WFQ is used: QOSC05: 512 bytes, QOSC04: 512 bytes, QOSC03: 512 bytes. 13.6.26 Classes Byte Limit Set 2 • Accessed by serial interface and I2C (R/W) C - QOSC06 – BYTE_C21 (CPU Address 51d) B - QOSC07 – BYTE_C22 (CPU Address 51e) 60 Zarlink Semiconductor Inc. MVTX2603 Data Sheet A - QOSC08 – BYTE_C23 (CPU Address 51f) QOSC06 through QOSC08 represents one set of values A-C for a 10/100 port when using the Weighted Random Early Detect (WRED) Scheme. Granularity when Delay bound is used: QOSC08: 128 bytes, QOSC07: 256 bytes. QOSC06: 512 bytes. Granularity when WFQ is used: QOSC08: 512 bytes, QOSC07: 512 bytes, QOSC06: 512 bytes. 13.6.27 Classes Byte Limit Set 3 • Accessed by serial interface and I2C (R/W) C - QOSC09 – BYTE_C31 (CPU Address 520) B - QOSC10 – BYTE_C32 (CPU Address 521) A - QOSC11 – BYTE_C33 (CPU Address 522) QOSC09 through QOSC011 represents one set of values A-C for a 10/100 port when using the Weighted Random Early Detect (WRED) Scheme. Granularity when Delay bound is used: QOSC11: 128 bytes, QOSC10: 256 bytes. QOSC09: 512 bytes. Granularity when WFQ is used: QOSC11: 512 bytes, QOSC10: 512 bytes, QOSC09: 512 bytes. 13.6.28 Classes Byte Limit Giga Port 1 • Accessed by serial interface and I2C (R/W) F - QOSC12 – BYTE_C2_G1 (I2C Address h0C7, CPU Address 523) E - QOSC13 – BYTE_C3_G1 (I2C Address h0C8, CPU Address 524) D - QOSC14 – BYTE_C4_G1 (I2C Address h0C9, CPU Address 525) C - QOSC15 – BYTE_C5_G1 (I2C Address h0CA, CPU Address 526) B - QOSC16 – BYTE_C6_G1 (I2C Address h0CB, CPU Address 527) A - QOSC17 – BYTE_C7_G1 (I2C Address h0CC, CPU Address 528) QOSC12 through QOSC17 represent the values A-F for Gigabit port 24. They are per-queue byte thresholds for random early drop. QOSC17 represents A, and QOSC12 represents F. Granularity when Delay bound is used: QOSC17 and QOSC16: 256 bytes, QOSC15 and QOSC14: 512 bytes, QOSC13 and QOSC12: 1024 bytes. Granularity when WFQ is used: QOSC17 to QOSC12: 1024 bytes 13.6.29 Classes Byte Limit Giga Port 2 • Accessed by serial interface and I2C (R/W) F - QOSC18 – BYTE_C2_G2 (I2C Address h0CD, CPU Address 529) E - QOSC19 – BYTE_C3_G2 (I2C Address h0CE, CPU Address 52a) D - QOSC20 – BYTE_C4_G2 (I2C Address h0CF, CPU Address 52b) C - QOSC21 – BYTE_C5_G2 (I2C Address h0D0, CPU Address 52c) B - QOSC22 – BYTE_C6_G2 (I2C Address h0D1, CPU Address 52d) A - QOSC23 – BYTE_C7_G2 (I2C Address h0D2, CPU Address 52e) QOSC18 through QOSC23 represent the values A-F for Gigabit port 2. They are per-queue byte thresholds for random early drop. QOSC23 represents A, and QOSC18 represents F. Zarlink Semiconductor Inc. 61 MVTX2603 Data Sheet Granularity when Delay Bound is used: QOSC23 and QOSC22: 256 bytes, QOSC21 and QOSC20: 512 bytes, QOSC19 and QOSC18: 1024 bytes. Granularity when WFQ is used: QOSC18 to QOSC23: 1024 bytes 13.6.30 Classes WFQ Credit Set 0 • Accessed by serial interface (R/W) W3 - QOSC24[5:0] – CREDIT_C00 (CPU Address 52f) W2 - QOSC25[5:0] – CREDIT_C01 (CPU Address 530) W1 - QOSC26[5:0] – CREDIT_C02 (CPU Address 531) W0 - QOSC27[5:0] – CREDIT_C03 (CPU Address 532) QOSC24 through QOSC27 represents one set of WFQ parameters for a 10/100 port. There are four such sets of values. The granularity of the numbers is 1, and their sum must be 64. QOSC27 corresponds to W0, and QOSC24 corresponds to W3. • QOSC24[7:6]: Priority service type for the ports select this parameter set. Option 1 to 4. • QOSC25[7]: Priority service allow flow control for the ports select this parameter set. • QOSC25[6]: Flow control pause best effort traffic only Both flow control allow and flow control best effort only can take effect only the priority type is WFQ. 13.6.31 Classes WFQ Credit Set 1 • Accessed by serial interface (R/W) W3 - QOSC28[5:0] – CREDIT_C10 (CPU Address 533) W2 - QOSC29[5:0] – CREDIT_C11 (CPU Address 534) W1 - QOSC30[5:0] – CREDIT_C12 (CPU Address 535) W0 - QOSC31[5:0] – CREDIT_C13 (CPU Address 536) QOSC28 through QOSC31 represents one set of WFQ parameters for a 10/100 port. There are four such sets of values. The granularity of the numbers is 1, and their sum must be 64. QOSC31 corresponds to W0, and QOSC28 corresponds to W3. QOSC28[7:6]: Priority service type for the ports select this parameter set. Option 1 to 4. QOSC29[7]: Priority service allow flow control for the ports select this parameter set. QOSC29[6]: Flow control pause best effort traffic only 13.6.32 Classes WFQ Credit Set 2 • Accessed by serial interface (R/W) W3 - QOSC32[5:0] – CREDIT_C20 (CPU Address 537) W2 - QOSC33[5:0] – CREDIT_C21 (CPU Address 538) W1 - QOSC34[5:0] – CREDIT_C22 (CPU Address 539) W0 - QOSC35[5:0] – CREDIT_C23 (CPU Address 53a) QOSC35 through QOSC32 represents one set of WFQ parameters for a 10/100 port. There are four such sets of values. The granularity of the numbers is 1, and their sum must be 64. QOSC35 corresponds to W0, and QOSC32 corresponds to W3. • • • 62 QOSC32[7:6]: Priority service type for the ports select this parameter set. Option 1 to option 4. QOSC33[7]: Priority service allow flow control for the ports select this parameter set. QOSC33[6]: Flow Control pause best effort traffic only Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.6.33 Classes WFQ Credit Set 3 • Accessed by serial interface (R/W) W3 - QOSC36[5;0] – CREDIT_C30 (CPU Address 53b) W2 - QOSC37[5:0] – CREDIT_C31 (CPU Address 53c) W1 - QOSC38[5:0] – CREDIT_C32 (CPU Address 53d) W0 - QOSC39[5:0] – CREDIT_C33 (CPU Address 53e) QOSC39 through QOSC36 represents one set of WFQ parameters for a 10/100 port. There are four such sets of values. The granularity of the numbers is 1, and their sum must be 64. QOSC39 corresponds to W0, and QOSC36 corresponds to W3. • • • QOSC36[7:6]: Priority service type for the ports select this parameter set. Option 1 to option 4. QOSC37[7]: Priority service allow flow control for the ports select this parameter set. QOSC37[6]: Flow Control pause best effort traffic only 13.6.34 Classes WFQ Credit Port G1 • Accessed by serial interface (R/W) W7 - QOSC40[5:0] – CREDIT_C0_G1 (CPU Address 53F) [7:6] - Priority service type. Option 1 to 4. W6 - QOSC41[5:0] – CREDIT_C1_G1 (CPU Address 540) [7]: Priority service allow flow control for the ports select this parameter set. [6]: Flow Control pause best effort traffic only W5 - QOSC42[5:0] – CREDIT_C2_G1 (CPU Address 541) W4 - QOSC43[5:0] – CREDIT_C3_G1 (CPU Address 542) W3 - QOSC44[5:0] – CREDIT_C4_G1 (CPU Address 543) W2 - QOSC45[5:0] – CREDIT_C5_G1 (CPU Address 544) W1 - QOSC46[5:0] – CREDIT_C6_G1 (CPU Address 545) W0 - QOSC47[5:0] – CREDIT_C7_G1 (CPU Address 546) QOSC40 through QOSC47 represents the set of WFQ parameters for Gigabit port 24. The granularity of the numbers is 1, and their sum must be 64. QOSC47 corresponds to W0, and QOSC40 corresponds to W7. In the 2G trunk configuration, the sum of all values QOSC40 through QOSC47 must equal 128. 13.6.35 Classes WFQ Credit Port G2 • Accessed by serial interface (R/W) W7 - QOSC48[5:0] – CREDIT_C0_G2 (CPU Address 547) [7:6] - Priority service type. Option 1 to 4. W6 - QOSC49[5:0] – CREDIT_C1_G2 (CPU Address 548) [7]: Priority service allow flow control for the ports select this parameter set. [6]: Flow Control pause best effort traffic only W5 - QOSC50[5:0] – CREDIT_C2_G2 (CPU Address 549) W4 - QOSC51[5:0] – CREDIT_C3_G2 (CPU Address 54a) W3 - QOSC52[5:0] – CREDIT_C4_G2 (CPU Address 54b) Zarlink Semiconductor Inc. 63 MVTX2603 Data Sheet W2 - QOSC53[5:0] – CREDIT_C5_G2 (CPU Address 54c) W1 - QOSC54[5:0] – CREDIT_C6_G2 (CPU Address 54d) W0 - QOSC55[5:0] – CREDIT_C7_G2 (CPU Address 54e) QOSC48 through QOSC55 represents the set of WFQ parameters for Gigabit port 25. The granularity of the numbers is 1, and their sum must be 64. QOSC55 corresponds to W0, and QOSC48 corresponds to W7. In the 2G trunk configuration, the sum of all values QOSC48 through QOSC55 must equal 128. 13.6.36 Class 6 Shaper Control Port G1 • Accessed by serial interface (R/W) • QOSC56[5:0] – TOKEN_RATE_G1 (Address 54f). Programs the average rate for Gigabit port 1. When equal to 0, shaper is disable. Granularity is 1. • QOSC57[7:0] – TOKEN_LIMIT_G1 (Address 550). Programs the maximum counter for Gigabit port1. Granularity is 16 bytes. Shaper is implemented to control the peak and average rate for outgoing traffic with priority 6 (queue 6). Shaper is limited to gigabit ports and queue P6 when it is in strict priority. QOSC41 programs the peak rate for Gigabit port 1. See Programming QoS Registers application note for more information. 13.6.37 Class 6 Shaper Control Port G2 • Accessed by serial interface (R/W) • QOSC58[5:0] – TOKEN_RATE_G2 (CPU Address 551). Programs the average rate for Gigabit port 2. When equal to 0, shaper is disable. Granularity is 1. • QOSC59[7:0] – TOKEN_LIMIT_G2 (CPU Address 552). Programs the maximum counter for Gigabit port2. Granularity is 16 bytes. Shaper is implemented to control the peak and average rate for outgoing traffic with priority 6 (queue 6). Shaper is limited to gigabit ports and queue P6 when it is in strict priority. QOSC49 programs the peak rate for Gigabit port 2. See Programming QoS Registers application note for more information. 13.6.38 RDRC0 – WRED Rate Control 0 • • I2C Address: h0FB, CPU Address: h553 Accessed by serial Interface and IcC (R/W) 7 0 X Rate Y Rate Bits [7:4]: • Corresponds to the frame drop percentage X% for WRED. Granularity 6.25%. Bits[3:0]: • Corresponds to the frame drop percentage Y% for WRED. Granularity 6.25%. See Programming QoS Registers application note for more information. 13.6.39 RDRC1 – WRED Rate Control 1 • • I2C Address: h0FC, CPU Address: h554 Accessed by serial Interface and I2C (R/W) 7 0 Z Rate 64 B Rate Zarlink Semiconductor Inc. MVTX2603 Data Sheet Bits [7:4]: • Corresponds to the frame drop percentage Z% for WRED. Granularity 6.25%. Bits[3:0]: • Corresponds to the best effort frame drop percentage B%, when shared pool is all in use and destination port best effort queue reaches UCC. Granularity 6.25%. See Programming QoS Register application note for more information. 13.6.40 User Defined Logical Ports and Well Known Ports The MVTX2600AG supports classifying packet priority through layer 4 logical port information. It can be setup by 8 Well Known Ports, 8 User Defined Logical Ports, and 1 User Defined Range. The 8 Well Known Ports supported are • 0:23 • 1:512 • 2:6000 • 3:443 • 4:111 • 5:22555 • 6:22 • 7:554 Their respective priority can be programmed via Well_Known_Port [7:0] priority register. Well_Known_Port_ Enable can individually turn on/off each Well Known Port if desired. Similarly, the User Defined Logical Port provides the user programmability to the priority, plus the flexibility to select specific logical ports to fit the applications. The 8 User Logical Ports can be programmed via User_Port 0-7 registers. Two registers are required to be programmed for the logical port number. The respective priority can be programmed to the User_Port [7:0] priority register. The port priority can be individually enabled/disabled via User_Port_Enable register. The User Defined Range provides a range of logical port numbers with the same priority level. Programming is similar to the User Defined Logical Port. Instead of programming a fixed port number, an upper and lower limit need to be programmed, they are: {RHIGHH, RHIGHL} and {RLOWH, RLOWL} respectively. If the value in the upper limit is smaller or equal to the lower limit, the function is disabled. Any IP packet with a logical port that is less than the upper limit and more than the lower limit will use the priority specified in RPRIORITY. 13.6.40.1USER_PORT0_(0~7) – User Define Logical Port (0~7) • • • • • • • • • USER_PORT_0 - I2C Address h0D6 + 0DE; CPU Address 580(Low) + 581(High) USER_PORT_1 - I2C Address h0D7 + 0DF; CPU Address 582 + 583 USER_PORT_2 - I2C Address h0D8 + 0E0; CPU Address 584 + 585 USER_PORT_3 - I2C Address h0D9 + 0E1; CPU Address 586 + 587 USER_PORT_4 - I2C Address h0DA + 0E2; CPU Address 588 + 589 USER_PORT_5 - I2C Address h0DB + 0E3; CPU Address 58a + 58b USER_PORT_6 - I2C Address h0DC + 0E4; CPU Address 58c + 58d USER_PORT_7 - I2C Address h0DD + 0E5; CPU Address 58e + 58f Accessed by serial interface and I2C (R/W) 7 0 TCP/UDP Logic Port Low Zarlink Semiconductor Inc. 65 MVTX2603 Data Sheet 7 0 TCP/UDP Logic Port High 66 Zarlink Semiconductor Inc. MVTX2603 Data Sheet • (Default 00) This register is duplicated eight times from PORT 0 through PORT 7 and allows the definition of eight separate ports. 13.6.40.2USER_PORT_[1:0]_PRIORITY - User Define Logic Port 1 and 0 Priority • • I2C Address: h0E6, CPU Address: h590 Accessed by serial interface and I2C (R/W) 7 5 4 Priority 1 • 3 Drop 1 Priority 0 0 Drop The chip allows the definition of the priority Bits[3:0]: • Priority setting, transmission + dropping, for logic port 0 Bits [7:4]: • Priority setting, transmission + dropping, for logic port 1 (Default 00) 13.6.40.3USER_PORT_[3:2]_PRIORITY - User Define Logic Port 3 and 2 Priority • • I2C Address: h0E7, CPU Address: h591 Accessed by serial interface and I2C (R/W) 7 5 4 Priority 3 3 Drop 1 0 Priority 2 Drop 13.6.40.4USER_PORT_[5:4]_PRIORITY - User Define Logic Port 5 and 4 Priority • • I2C Address: h0E8, CPU Address: h592 Accessed by serial interface and I2C (R/W) 7 5 4 Priority 5 • 3 Drop 1 0 Priority 4 Drop (Default 00) 13.6.40.5USER_PORT_[7:6]_PRIORITY - User Define Logic Port 7 and 6 Priority • • I2C Address: h0E9, CPU Address: h593 Accessed by serial interface and I2C (R/W) 7 5 4 Priority 7 • 3 Drop 1 0 Priority 6 Drop (Default 00) 13.6.40.6USER_PORT_ENABLE [7:0] – User Define Logic 7 to 0 Port Enables • • • I2C Address: h0EA, CPU Address: h594 Accessed by serial interface and I2C (R/W) 7 6 5 4 3 2 1 0 P7 P6 P5 P4 P3 P2 P1 P0 (Default 00) Zarlink Semiconductor Inc. 67 MVTX2603 Data Sheet 13.6.40.7WELL_KNOWN_PORT [1:0] PRIORITY- Well Known Logic Port 1 and 0 Priority • • I2C Address: h0EB, CPU Address: h595 Accessed by serial interface and I2C (R/W) 7 5 Priority 1 • • • 4 3 Drop 1 Priority 0 0 Drop Priority 0 - Well known port 23 for telnet applications. Priority 1 - Well known port 512 for TCP/UDP (Default 00) 13.6.40.8WELL_KNOWN_PORT [3:2] PRIORITY- Well Known Logic Port 3 and 2 Priority • • I2C Address: h0EC, CPU Address: h596 Accessed by serial interface and I2C (R/W) 7 5 4 Priority 3 • • • 3 Drop 1 Priority 2 0 Drop Priority 2 - Well known port 6000 for XWIN. Priority 3 - Well known port 443 for http. sec (Default 00) 13.6.40.9WELL_KNOWN_PORT [5:4] PRIORITY- Well Known Logic Port 5 and 4 Priority • • I2C Address: h0ED, CPU Address: h597 Accessed by serial interface and I2C (R/W) 7 5 4 Priority 5 • • • 3 Drop 1 Priority 4 0 Drop Priority 4 - Well known port 111 for sun rpe. Priority 5 - Well known port 22555 for IP Phone call setup. (Default 00) 13.6.40.10WELL_KNOWN_PORT [7:6] PRIORITY- Well Known Logic Port 7 and 6 Priority • • I2C Address: h0EE, CPU Address: h598 Accessed by serial interface and I2C (R/W) 7 5 Priority 7 • • • 68 4 Drop 3 1 Priority 6 Priority 6 - Well known port 22 for ssh. Priority 7 - Well known port 554 for rtsp. (Default 00) Zarlink Semiconductor Inc. 0 Drop MVTX2603 Data Sheet 13.6.40.11WELL KNOWN_PORT_ENABLE [7:0] – Well Known Logic 7 to 0 Port Enables • • I2C Address: h0EF, CPU Address: h599 Accessed by serial interface and I2C (R/W) 7 6 5 4 3 2 1 0 P7 P6 P5 P4 P3 P2 P1 P0 • 1 - Enable • 0 - Disable • (Default 00) 13.6.40.12RLOWL – User Define Range Low Bit 7:0 • • • I2C Address: h0F4, CPU Address: h59a Accessed by serial interface and I2C (R/W) (Default 00) 13.6.40.13RLOWH – User Define Range Low Bit 15:8 • • • I2C Address: h0F5, CPU Address: h59b Accessed by serial interface and I2C (R/W) (Default 00) 13.6.40.14RHIGHL – User Define Range High Bit 7:0 • • • I2C Address: h0D3, CPU Address: h59c Accessed by serial interface and I2C (R/W) (Default 00) 13.6.40.15RHIGHH – User Define Range High Bit 15:8 • • • I2C Address: h0D4, CPU Address: h59d Accessed by serial interface and I2C (R/W) (Default 00) 13.6.40.16RPRIORITY – User Define Range Priority • • I2C Address: h0D5, CPU Address: h59e Accessed by serial interface and I2C (R/W) 7 3 0 Range Transmit Priority • Drop RLOW and RHIGH form a range for logical ports to be classified with priority specified in RPRIORITY. Bit[3:1] • Transmit Priority Bits[0]: • Drop Priority Zarlink Semiconductor Inc. 69 MVTX2603 Data Sheet 13.7 Group 6 Address MISC Group 13.7.1 MII_OP0 – MII Register Option 0 • • I 2C Address: hF0, CPU Address:h600 Accessed by serial interface and I2C (R/W) 7 6 hfc Bits [7]: 5 4 0 1prst • Vendor Spc. Reg Addr Half duplex flow control feature • 0 = Half duplex flow control always enable • 1 = Half duplex flow control by negotiation Bits[6]: • Link partner reset auto-negotiate disable Bits[5]: • Disable jabber detection. This is for HomePNA application or any serial operation slower than 10Mbps. • 1 = disable • 0 = enable Bit[4:0]: 13.7.2 • • • Vendor specified link status register address (null value means don’t use it) (Default 00); used when the Linkup bit position in the PHY is non-standard. MII_OP1 – MII Register Option 1 I 2C Address: hF1, CPU Address:h601 Accessed by serial interface and I2C (R/W) 7 4 3 Speed bit location 70 0 Duplex bit location Bits[3:0]: • Duplex bit location in vendor specified register Bits [7:4]: • • Speed bit location in vendor specified register (Default 00) Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.7.3 • • FEN – Feature Register I2C Address: hF2, CPU Address: h602 Accessed by serial interface and I2C (R/W) 7 0 DML MII DS Bits [0]: • Reserved (Default 0) Bits[1]: • Reserved (Default 0) Bit [2]: • • Support DS EF Code. (Default 0) When 101110 is detected in DS field (TOS [7:2]), the frame priority is set for 110 and drop is set for 0. Bit [3]: • Reserved (Default 0) Bit [4]: • Reserved (Default 1) Bit [5]: • Reserved (Default 0) Bit [6]: • Disable MII Management State Machine • 0: Enable MII Management State Machine (Default 0) • 1: Disable MII Management State Machine Bit [7]: • Disable using MCT link list structure • 0: Enable using MCT Link List structure (Default 0) • 1: Disable using MCT Link List structure 13.7.4 MIIC0 – MII Command Register 0 • CPU Address: h603 • Accessed by serial interface only (R/W) • Bit [7:0] MII Data [7:0] Note: Before programming MII command: set FEN[6], check MIIC3, making sure no RDY, and no VALID; then program MII command. 13.7.5 MIIC1 – MII Command Register 1 • CPU Address: h604 • Accessed by serial interface only (R/W) • Bit [7:0] MII Data [15:8] Note: Before programming MII command: set FEN[6], check MIIC3, making sure no RDY and no VALID; then program MII command. Zarlink Semiconductor Inc. 71 MVTX2603 13.7.6 • • Data Sheet MIIC2 – MII Command Register 2 CPU Address :h605 Accessed by serial interface only (R/W) 7 0 Mii OP Register address Bits [4:0]: • REG_AD – Register PHY Address Bit [6:5] • OP – Operation code “10” for read command and “01” for write command Note: Before programming MII command: set FEN[6], check MIIC3, making sure no RDY and no VALID; then program MII command. Writing to this register will initiate a serial management cycle to the MII management interface. For detail information, please refer to the PHY Control Application Note. 13.7.7 • • MIIC3 – MII Command Register 3 CPU Address: h606 Accessed by serial interface only (R/W) 7 0 Rdy Valid PHY address Bits [4:0]: • PHY_AD – 5 Bit PHY Address Bit [6] • VALID – Data Valid from PHY (Read Only) Bit [7] • RDY – Data is returned from PHY (Ready Only) Note: Before programming MII command: set FEN[6], check MIIC3, making sure no RDY and no VALID; then program MII command. 13.7.8 • • • CPU Address: h607 Accessed by serial interface only (RO) Bit [7:0] MII Data [7:0] 13.7.9 • • • MIID0 – MII Data Register 0 MIID1 – MII Data Register 1 CPU Address: h608 Accessed by serial interface only (RO) Bit [7:0] MII Data [15:8] 13.7.10 LED Mode – LED Control • • CPU Address: h609 Accessed by serial interface and I2C (R/W) 7 0 Clock rate 72 Zarlink Semiconductor Inc. Hold Time MVTX2603 Data Sheet Bit [0] • Reserved (Default 0) Bit[2:1]: • Hold time for LED signal (Default= 00) • 00=8msec 01=16msec 10=32msec 11=64msec Bit[4:3]: • LED clock frequency (Default 0) For 100MHz SCLK 00=100M/8=12.5 MHz 10=100M/32=3.125 MHz 01=100M/16= 6.25 MHz 11=100M/64=1.5625 MHz For 125MHz SCLK 00=125M/64=1953 KHz 01=125M/128=977KHz 10=125M/512=244 KHz 11=125M/1024=122KHz Bit[6]: • Reserved. Must be 0. (Default 0) Bit[7]: • Reserved. Must be 0. (Default 0) 13.7.11 CHECKSUM - EEPROM Checksum • • I2C Address: FF, CPU Address: h60b Accessed by serial interface and I2C (R/W) Bit [7:0]: • (Default 0) Before requesting that the MVTX2603AG updates the EEPROM device, the correct checksum needs to be calculated and written into this checksum register. When the MVTX2604AG boots from the EEPROM the checksum is calculated and the value must be zero. If the checksum is not zeroed the MVTX2604AG does not start and pin CHECKSUM_OK is set to zero. The checksum formula is: FF Σ I2C register = 0 I=0 13.8 Group 7 Address Port Mirroring Group 13.8.1 MIRROR1_SRC – Port Mirror source port • • CPU Address: h700 Accessed by serial interface (R/W) (Default 7F) 7 0 OV I/O Src Port Select Bit [4:0]: • Source port to be mirrored. Use illegal port number to disable mirroring Bit [5]: • • 1 – select ingress data 0 – select egress data Bit [7]: • Must be ‘1’ Zarlink Semiconductor Inc. 73 MVTX2603 13.8.2 • • Data Sheet MIRROR1_DEST – Port Mirror destination CPU Address: h701 Accessed by serial interface (R/W) (Default 17) 7 0 Dest Port Select Bit [4:0]: 13.8.3 • • • Port Mirror Destination MIRROR2_SRC – Port Mirror source port CPU Address: h702 Accessed by serial interface (R/W) (Default FF) 7 0 I/O 13.8.4 • • Src Port Select Bit [4:0]: • Source port to be mirrored. Use illegal port number to disable mirroring Bit [5]: • • 1 – select ingress data 0 – select egress data Bit [7] • Must be 1 MIRROR2_DEST – Port Mirror destination CPU Address: h703 Accessed by serial interface (R/W) (Default 00) 7 0 Dest Port Select Bit [4:0]: • Port Mirror Destination 13.9 Group F Address CPU Access Group 13.9.1 GCR-Global Control Register • • CPU Address: hF00 Accessed by serial interface. (R/W) 7 0 Reset 74 Bist SR SC Bit [0]: • • Store configuration (Default = 0) Write ‘1’ followed by ‘0’ to store configuration into external EEPROM Bit[1]: • • Store configuration and reset (Default = 0) Write ‘1’ to store configuration into external EEPROM and reset chip Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.9.2 • • Bit[2]: • • Start BIST (Default = 0) Write ‘1’ followed by ‘0’ to start the device’s built-in self-test. The result is found in the DCR register. Bit[3]: • • Soft Reset (Default = 0) Write ‘1’ to reset chip Bit[4]: • Reserved. DCR-Device Status and Signature Register CPU Address: hF01 Accessed by serial interface. (RO) 7 0 Revision 13.9.3 • • Signature RE BinP Bit [0]: • • 1: Busy writing configuration to I2C 0: Not busy writing configuration to I2C Bit[1]: • • 1: Busy reading configuration from I2C 0: Not busy reading configuration from I2C Bit[2]: • • 1: BIST in progress 0: BIST not running Bit[3]: • • 1: RAM Error 0: RAM OK Bit[5:4]: • • Device Signature 01: MVTX2603AG device Bit [7:6]: • • • Revision 00: Initial Silicon 01: XA1 Silicon BR BW DCR1-Giga port status CPU Address: hF02 Accessed by serial interface (RO) 7 3 CIC Bit [1:0]: 2 GIGA1 • • • • • 1 0 GIGA0 Giga port 0 strap option 00 – 100Mb MII mode 01 – 2G mode 10 – GMII 11 – PCS Zarlink Semiconductor Inc. 75 MVTX2603 13.9.4 • • Data Sheet Bit[3:2] • • • • • Giga port 1 strap option 00 – 100Mb MII mode 01 – 2G mode 10 – GMII 11 – PCS Bit [7] • Chip initialization completed DPST – Device Port Status Register CPU Address: hF03 Accessed by serial interface (R/W) Bit[4:0]: • Read back index register. This is used for selecting what to read back from DTST. (Default 00) - 76 5’b00000 - Port 0 Operating mode and Negotiation status 5’b00001 - Port 1 Operating mode/Neg status 5’b00010 - Port 2 Operating mode/Neg status 5’b00011 - Port 3 Operating mode/Neg status 5’b00100 - Port 4 Operating mode/Neg status 5’b00101 - Port 5 Operating mode/Neg status 5’b00110 - Port 6 Operating mode/Neg status 5’b00111 - Port 7 Operating mode/Neg status 5’b01000 - Port 8 Operating mode/Neg status 5’b01001 - Port 9 Operating mode/Neg status 5’b01010 - Port 10 Operating mode/Neg status 5’b01011 - Port 11 Operating mode/Neg status 5’b01100 - Port 12 Operating mode/Neg status 5’b01101 - Port 13 Operating mode/Neg status 5’b01110 - Port 14 Operating mode/Neg status 5’b01111 - Port 15 Operating mode/Neg status 5’b10000 - Port 16 Operating mode/Neg status 5’b10001 - Port 17 Operating mode/Neg status 5’b10010 - Port 18 Operating mode/Neg status 5’b00011 - Port 19 Operating mode/Neg status 5’b10100 - Port 20 Operating mode/Neg status 5’b10101 - Port 21 Operating mode/Neg status 5’b10110 - Port 22 Operating mode/Neg status 5’b10111 - Port 23 Operating mode/Neg status 5’b11000 - Port 24 Operating mode/Neg status (CPU port -Not used) 5’b11001 - Port 25 Operating mode/Neg status (Gigabit port 1) 5’b11010 - Port 26 Operating mode/Neg status (Gigabit port 2) Zarlink Semiconductor Inc. MVTX2603 Data Sheet 13.9.5 • • • DTST – Data read back register CPU Address: hF04 Accessed by serial interface (RO) This register provides various internal information as selected in DPST bit[4:0]. Refer to the PHY Control Application Note. MD Info Sig Giga Inkdn FE Fdpx FcEn When bit is 1 • • • • • • • • Bit[0] Bit[1] Bit[2] Bit[3] Bit[4] Bit[5] Bit[6] Bit[7] 13.9.6 • • • – Flow control enable – Full duplex port – Fast Ethernet port (if not gigabit port) – Link is down – Giga port – Signal detect (when PCS interface mode) – 2G signal detect (2G mode only) – Module detected (for hot swap purpose) DA – DA Register CPU Address: hFFF Accessed by CPU and serial interface (RO) Always return 8’h DA. Indicate the serial port connection is good. 13.10 TBI Registers Two sets of TBI registers are used for configure the two Gigabit ports if they are operating in TBI mode. These TBI registers are located inside the switching chip and they are accessed through the MII command and MII data registers. 13.10.1 Control Register • • MII Address: h00 Read/Write Bit [15] Reset PCS logic and all TBI registers 1 = Reset. 0 = Normal operation. Bit [14] Reserved. Must be programmed with “0”. Bit [13] Speed selection (See bit 6 for complete details) Bit [12] • • • Auto Negotiation Enable 1 = Enable auto-negotiation process. 0 = Disable auto-negotiation process (Default). Bit [11:10] • Reserved. Must be programmed with “0” Bit [9] • • • Restart Auto Negotiation. 1 = Restart auto-negotiation process. 0 = Normal operation (Default). Bit [8:7] • Reserved. Zarlink Semiconductor Inc. 77 MVTX2603 Bit [6] Data Sheet • Speed Selection - Bit [5:0] • Bit[6][13] 1 1 = Reserved 0 =1000Mb/s (Default) 1 =100Mb/s 0 0 =10Mb/s Reserved. Must be programmed with “0”. 13.10.2 Status Register • • MII Address: h01 Read Only Bit [15:9] Reserved. Always read back as “0”. Bit [8] Reserved. Always read back as “1”. Bit [7:6] Reserved. Always read back as “0”. Bit [5] • • • Auto-Negotiation Complete 1 = Auto-negotiation process completed. 0 = Auto-negotiation process not completed. Bit [4] • Reserved. Always read back as “0” Bit [3] • Reserved. Always read back as “1” Bit [2] • • • Link Status 1 = Link is up. 0 = Link is down. Bit [1] • Reserved. Always read back as “0”. Bit [0] • Reserved. Always read back as “1”. 13.10.3 Advertisement Register • • 78 MII Address: h04 Read/Write Bit [15] Next Page 1 = Has next page capabilities. 0 = Do not has next page capabilities (Default). Bit [14] Reserved. Always read back as “0”. Read Only. Bit [13:12] Remote Fault. Default is “0”. Bit [11:9] • Reserved. Always read back as “0”. Read Only. Bit [8:7] • Pause. Default is “00” Bit [6] • • • Half Duplex 1 = Support half duplex (Default). 0 = Do not support half duplex. Zarlink Semiconductor Inc. MVTX2603 Data Sheet Bit [5] • • • Full duplex 1 = Support full duplex (Default). 0 = Do not support full duplex. Bit [4:0] • Reserved. Always read back as “0”. Read Only. 13.10.4 Link Partner Ability Register • • MII Address: h05 Read Only Bit [15] Next Page 1 = Has next page capabilities. 0 = Do not has next page capabilities. Bit [14] Acknowledge Bit [13:12] Remote Fault. Bit [11:9] • Reserved. Always read back as “0”. Bit [8:7] • Pause. Bit [6] • • • Half Duplex 1 = Support half duplex. 0 = Do not support half duplex. Bit [5] • • • Full duplex 1 = Support full duplex. 0 = Do not support full duplex. Bit [4:0] • Reserved. Always read back as “0”. 13.10.5 Expansion Register • • MII Address: h06 Read Only Bit [15:2] • Reserved. Always read back as “0”. Bit [1] • • • Page Received. 1 = A new page has been received. 0 = A new page has not been received. Bit [0] • Reserved. Always read back as “0”. Zarlink Semiconductor Inc. 79 MVTX2603 Data Sheet 13.10.6 Extended Status Register • • 80 MII Address: h15 Read Only Bit [15] • • • 1000 Full Duplex 1 = Support 1000 full duplex operation (Default). 0 = Do not support 1000 full duplex operation. Bit [14] • • • 1000 Half Duplex 1 = Support 1000 half duplex operation (Default). 0 = Do not support 1000 half duplex operation. Bit [13:0] • Reserved. Always read back as “0”. Zarlink Semiconductor Inc. MVTX2603 Data Sheet 14.0 BGA and Ball Signal Descriptions 14.1 BGA Views 14.1.1 Encapsulated View 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 A LA_D LA_D LA_D LA _D LA_D LA_A LA_O LA_A LA_A LA_A LA_A LA _D LA_D LA_D LA_D LA_D RE SE RE SE T RUN RE SE RESE SC L 4 7 10 13 15 4 E0_ 8 13 16 19 33 36 39 42 45 RVED RVED K 1 RVED RV ED B LA_D LA_D LA_D LA_D LA _D LA_D LA_A LA_O LA_A LA_A LA_A LA_A LA _D LA_D LA_D LA_D LA_D RE SE RE SE LA _D RE SE RESE TRUN RESE 1 3 6 9 12 14 DSC_ E1_ 7 12 15 18 32 35 38 41 44 RVED RVED 62 RVED RV ED K2 RVED SDA 26 27 28 29 ST RO TSTO BE UT 7 D0 TSTO TSTO UT 8 UT 3 C LA_C LA_D LA_D LA_D LA_D LA _D LA_A LA_O LA_W T_MO LA_A LA_A LA_A LA _A LA_D LA_D LA_D LA_D RE SE RE SE RE SE T RUN RESE RESE AUT O T STO TSTO TSTO TSTO LK 0 2 5 8 11 3 E_ E_ D E1 11 14 17 20 34 37 40 43 RVED RVED RVED K0 RV ED RVED FD UT 11 UT 9 UT 4 UT 0 D AG N LA_D LA_D LA_D LA_D LA _D LA_D LA_D LA_D LA_A LA_A LA_W LA_D LA _D LA_D LA_D LA_D LA_D LA_D LA_D LA _D SCAN SCAN T STO T STO T STO T STO TSTO TSTO D 17 19 21 23 25 27 29 31 6 10 E0 _ 49 51 53 55 57 59 61 63 47 C OL CLK UT 14 UT 13 UT 12 UT10 UT 5 UT 1 SCAN SCAN T STO M26_ M26_ MOD LINK UT 15 CRS T XE R E M26_ M26_ M26_ MTX T XC L T XEN C LK K LA_D LA_D LA_D LA_D LA _D LA_D LA_D LA_D LA_A LA_A LA_W LA_D LA _D LA_D LA_D LA_D LA_D LA_D RE SE LA _D E SC LK 16 18 20 22 24 26 28 30 5 9 E1 _ 48 50 52 54 56 58 60 RVED 46 F AVC C RESI SC AN LB_D LB_D N_ EN 63 62 G RESE LB_C LB_D LB_D LB_D TOUT LK 47 61 60 _ VDD VDD 33 33 VDD 33 VDD VDD 33 33 M26_ T XD1 4 M26_ T XD1 2 M26_ T XD1 0 LB_D LB_D LB_D LB_D LB_D H 46 45 44 59 58 J LB_D LB_D LB_D LB_D LB_D 43 42 41 57 56 K LB_D LB_D LB_D LB_D LB_D 40 39 38 55 54 VDD VDD M26_ T XD1 5 M26_ T XD1 3 M26_ T XD1 1 M26_ RXD1 5 M26_ RXD1 2 TSTO TSTO UT 6 UT 2 M26_ M26_ RXD RXCL V K M26_ M26_ RXER COL M26_ RXD1 3 M26_ M26_ R XD1 RXD9 0 M26_ RX D1 4 M26_ RX D1 1 M26_ M26_ M26_ M26_ M26_ T XD9 T XD8 RXD6 RXD7 RX D8 VDD VDD L LB_D LB_D LB_D LB_D LB_D 37 36 35 53 52 M26_ M26_ M26_ M26_ M26_ T XD4 T XD6 RXD3 RXD4 RX D5 M LB_D LB_D LB_D LB_D LB_D 34 33 32 51 50 VDD VSS VSS VSS VSS VSS VSS VSS VDD N LB_A LB_A LB_A LB_D LB_D VDD 18 19 20 49 48 33 VDD VSS VSS VSS VSS VSS VSS VSS VDD P LB_A LB_A LB_A LB_W LB_ VDD 15 16 17 E0 _ WE1_ 33 VSS VSS VSS VSS VSS VSS VSS VDD M26 _ M26_ 33 T XD0 T XD1 R LB_A LB_A LB_A LB_A LB_A VDD 10 11 12 13 14 33 VSS VSS VSS VSS VSS VSS VSS VDD M25 _ M25_ 33 C RS T XE R M25 _ M25_ M25_ M25_ M25_ VDD T XCL MTX RXD RXCL 33 T XEN K CLK V K T LB_A LB_A LB_A LB_A LB_A VDD 5 6 7 8 9 33 LB_O LB_O T_MO LB_D LB_D VDD U E0_ E1_ D E0 31 30 33 V LB_A LB_O LB_W LB_D LB_D DSC_ E_ E_ 29 28 W LB_D LB_A LB_A LB_D LB_D 15 3 4 27 26 Y LB_D LB_D LB_D LB_D LB_D 14 13 12 25 24 VSS VSS VSS VSS VSS VSS VSS VDD VSS VSS VSS VSS VSS VSS VSS VDD VDD VSS VSS VSS VSS VSS VSS VSS VDD VDD VDD M26_ M26_ M26_ M26_ M26_ T XD7 T XD5 RXD0 RXD1 RX D2 GRE F _CLK 1 GRE F MDIO _CLK 0 VDD M26 _ M26_ 33 T XD2 T XD3 M25 _ VDD 3 3 T X4D 1 M25_ T XD1 2 M25_ T XD1 0 M25_ T XD1 5 M25_ T XD1 3 M25_ T XD1 1 MDC M25_ RXD1 5 M25_ RXD1 2 M_CL K M25_ M25_ RXER COL M25_ RXD1 3 M25_ M25_ RXD1 RXD9 0 M25_ RX D1 4 M25_ RX D1 1 M25_ M25_ M25_ M25_ M25_ RXD6 T XD8 T XD9 RXD7 RX D8 VDD VDD A LB_D LB_D LB_D LB_D LB_D 11 10 9 23 22 A M25_ M25_ M25_ M25_ M25_ T XD6 T XD7 RXD3 RXD4 RX D5 A LB_D LB_D LB_D LB_D LB_D 8 7 6 21 20 B M25_ M25_ M25_ M25_ M25_ T XD4 T XD5 RXD0 RXD1 RX D2 A LB_D LB_D LB_D LB_D LB_D 5 4 3 19 18 C M25_ M25_ M23_ M23_ M23_ T XD2 T XD3 C RS RXD0 RX D1 A LB_D LB_D LB_D LB_D LB_D 2 1 0 17 16 D VDD VDD 33 33 VDD 33 VDD VDD 33 33 M25_ M25_ M23_ M23_ M23_ T XD0 T XD1 T XD1 T XD0 T XEN A M0_T M0_T M0_T M3_T M3_T M3_ R M5_T M5_T M5_R M8_T M8_T M8_R M10_ M10_ M10_ M13_ M16_ M15_ M16_ M15_ M15_ M18_ M18_ M18_ M20_ M20_ M20_ M22_ E XEN XD0 XD1 X D1 XEN XD 0 XD1 XEN XD0 XD1 XEN X D0 T XD1 T XEN RXD 0 TXD1 T XD0 T XD1 RXD1 T XEN RX D0 TXD1 TXEN RXD0 T XD1 T XEN RXD0 RXD1 AF M0_R M0_R M0_C M3_T M3_C M3_ R M5_T M5_C M5_R M8_T M8_C M8_R M10_ M10_ M10_ M13_ M13_ M13_ M14_ M16R M15_ M17_ M17_ M18_ M20_ M20_ M20_ M22_ M22_ XD1 XD0 RS XD0 RS XD1 XD0 RS XD1 XD0 RS X D1 T XD0 CRS RXD 1 TXD0 CRS RXD1 C RS X D0 RX D1 RXD 0 CRS RXD1 T XD0 C RS RXD1 RXD0 CRS A M1_T M1_T M1_T M2_T M2_C M4_T M4_C M6_T M6_C M7_T M7_C M9_T M9_C M11_ M11_ M12_ M12_ M14_ M15_ M16_ M16_ M18_ M18_ M19_ M19_ M21_ M21_ M22_ M22_ RS XD1 RS XD1 RS XD1 RS XD1 RS TXD1 CRS TXD1 CRS T XD1 T XD0 T XD1 CRS TXD0 CRS T XD1 CRS T XD1 C RS T XEN TXD0 G XEN XD0 XD1 XD1 M1_R M1_C M2_T M2_R M4_T M4_R M6_T M6_R M7_T M7_R M9_T M9_R M11_ M11_ M12_ M12_ M14_ M14_ M13_ M15_ M17_ M17_ M19_ M19_ M21_ M21_ M22_ XD0 RS X D0 X D0 XD 0 XD0 XD0 XD0 XD0 XD0 X D0 X D0 TXD0 RXD 0 TXD0 RXD0 T XD0 RXD0 RXD0 CRS TXD0 RXD 1 T XD0 RXD0 T XD0 RXD0 T XD1 A H M1_R M2_T M2_R M4_T M4_R M6_T M6_R M7_T M7_R M9_T M9_R M11_ M11_ M12_ M12_ M14_ M14_ M16_ M13_ M17_ M17_ M19_ M19_ M21_ M21_ XD1 XEN X D1 X EN XD1 XEN XD1 XEN XD1 XEN X D1 T XEN RXD 1 TXEN RXD1 TXEN RXD1 T XEN T XEN TXEN TXD1 TXEN RXD1 TXEN RXD1 AJ 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 Figure 18 - BGA View Zarlink Semiconductor Inc. 81 MVTX2603 14.1.2 Data Sheet Power and Ground Distribution The following figure provides an encapsulated view of the power and ground distribution 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 A LA_ D LA_ D LA_ D LA_ D LA_ D LA_ A LA_ O LA_ A LA_ A LA_ A LA_ A LA_ D LA_ D LA_ D LA_ D LA_ D R ESE R ES E TR UN MIR R MIR R S C L 4 7 10 13 15 4 E0 8 13 16 19 33 36 39 42 4 5 R VED R VED K1 OR 4 OR 1 B LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ A LA_ O LA_ A LA_ A LA_ A LA_ A LA_ D LA_ D LA_ D LA_ D LA_ D R ESE R ES E LA_ D MIR R MIR R TR UN R ES E 1 3 6 9 12 1 4 DSC E1 7 12 15 18 32 35 38 41 4 4 R VED R VED 6 2 OR 5 OR 2 K2 R VED 26 27 28 29 SDA STR O TS TO B E UT7 D0 TS TO TSTO UT8 UT3 C LA_ C LA_ D LA_ D LA_ D LA_ D LA_ D LA_ A LA_ O LA W T_ MO LA_ A LA_ A LA_ A LA_ A LA_ D LA_ D LA_ D LA_ D R ESE R ES E R ESE TR UN MIR R MIR R AUTO TS TO TS TO TSTO TS TO E_ DE1 11 14 17 20 34 37 40 4 3 R VED R VED R VED K0 OR 3 OR 0 FD UT1 1 UT9 UT4 UT0 LK 0 2 5 8 11 3 E_ D AGN LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ A LA_ A LA W LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D S C AN S C AN TS TO TSTO TS TO TS TO TSTO TS TO E0 49 51 53 55 57 59 61 63 47 C OL C LK UT1 4 UT1 3 UT1 2 UT1 0 UT5 UT1 D 17 19 21 23 25 27 29 31 6 10 S C AN TS TO M2 6 _ M2 6 _ SC AN TSTO TS TO LINK UT1 5 C R S TXER MOD UT6 UT2 E M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXC L TXEN MTX R XD R XC L K C LK V K M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXD1 TXD1 R XD1 R XER C OL 4 5 5 M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXD1 TXD1 R XD1 R XD1 R XD1 2 3 2 3 4 M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXD1 TXD1 R XD9 R XD1 R XD1 0 1 0 1 LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ A LA_ A LA W LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D LA_ D R ES E LA_ D E SC LK 1 6 18 20 22 24 26 28 30 5 9 E1 48 50 52 54 56 58 6 0 R VED 4 6 F AVC R ESI S C AN LB _ D LB _ D C N_ EN 63 62 VDD VDD VDD VDD VDD 33 33 33 33 33 LB _ C R ESE LB _ D LB _ D LB _ D G LK TOUT 4 7 61 60 _ H LB _ D LB _ D LB _ D LB _ D LB _ D 46 45 44 59 58 LB _ D LB _ D LB _ D LB _ D LB _ D J 43 42 41 57 56 K LB _ D LB _ D LB _ D LB _ D LB _ D 40 39 38 55 54 VDD VDD M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXD9 TXD8 R XD6 R XD7 R XD8 VDD VDD L LB _ D LB _ D LB _ D LB _ D LB _ D 37 36 35 53 52 M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXD4 TXD6 R XD3 R XD4 R XD5 M LB _ D LB _ D LB _ D LB _ D LB _ D 34 33 32 51 50 VDD VS S VSS VS S VSS VS S VS S VSS VDD N LB _ A LB _ A LB _ A LB _ D LB _ D VDD 18 19 20 49 48 33 VDD VS S VSS VS S VSS VS S VS S VSS VDD P LB _ A LB _ A LB _ A LB W LB _ E0 W E1 15 16 17 VDD 33 VS S VSS VS S VSS VS S VS S VSS LB _ A LB _ A LB _ A LB _ A LB _ A VDD R 10 11 12 13 14 33 VS S VSS VS S VSS VS S VS S VSS T LB _ A LB _ A LB _ A LB _ A LB _ A VDD 5 6 7 8 9 33 U LB _ O LB _ O T_ MO LB _ D LB _ D VDD E0 E1 DE0 31 30 33 LB _ A LB _ O LB W LB _ D LB _ D V DS C E_ 29 28 E_ VS S VSS VS S VSS VS S VS S VSS VDD VS S VSS VS S VSS VS S VS S VSS VDD VDD VS S VSS VS S VSS VS S VS S VSS VDD M2 6 _ M2 6 _ M2 6 _ M2 6 _ M2 6 _ TXD7 TXD5 R XD0 R XD1 R XD2 VDD M2 6 _ M2 6 _ D_ C O D_ C O GR EF 3 3 TXD2 TXD3 NF IG NFIG _ C LK 1 0 1 GR EF VDD M2 6 _ M2 6 _ MDIO _ C LK 3 3 TXD0 TXD1 0 LB _ D LB _ A LB _ A LB _ D LB _ D W 15 3 4 27 26 Y LB _ D LB _ D LB _ D LB _ D LB _ D 14 13 12 25 24 VDD VDD VDD M2 5 _ M2 5 _ 33 C R S TXER MDC M_ C L K VDD M2 5 _ M2 5 _ 3 3 TXC L TXEN K VDD M2 5 _ M2 5 _ 3 3 TXD1 TXD1 4 5 M2 5 _ M2 5 _ TXD1 TXD1 2 3 M2 5 _ M2 5 _ TXD1 TXD1 0 1 M2 5 _ M2 5 _ M2 5 _ MTX R XD R XC L C LK V K M2 5 _ M2 5 _ M2 5 _ R XD1 R XER C OL 5 M2 5 _ M2 5 _ M2 5 _ R XD1 R XD1 R XD1 2 3 4 M2 5 _ M2 5 _ M2 5 _ R XD1 R XD1 R XD9 0 1 M2 5 _ M2 5 _ M2 5 _ M2 5 _ M2 5 _ R XD6 TXD8 TXD9 R XD7 R XD8 VDD VDD LB _ D LB _ D LB _ D LB _ D LB _ D 11 10 9 23 22 M2 5 _ M2 5 _ M2 5 _ M2 5 _ M2 5 _ TXD6 TXD7 R XD3 R XD4 R XD5 A LB _ D LB _ D LB _ D LB _ D LB _ D 8 7 6 21 20 B M2 5 _ M2 5 _ M2 5 _ M2 5 _ M2 5 _ TXD4 TXD5 R XD0 R XD1 R XD2 A LB _ D LB _ D LB _ D LB _ D LB _ D 5 4 3 19 18 C M2 5 _ M2 5 _ M2 3 _ M2 3 _ M2 3 _ TXD2 TXD3 C R S R XD0 R XD1 A A A D LB _ D LB _ D LB _ D LB _ D LB _ D 2 1 0 17 16 VDD VDD VDD VDD VDD 33 33 33 33 33 M2 5 _ M2 5 _ M2 3 _ M2 3 _ M2 3 _ TXD0 TXD1 TXD1 TXD0 TXEN M0 _ T M0 _ T M0 _ T M3 _ T M3 _ T M3 _ R M5 _ T M5 _ T M5 _ R M8 _ T M8 _ T M8 _ R M1 0 _ M1 0 _ M1 0 _ M1 3 _ M1 6 _ M1 5 _ M1 6 _ M1 5 _ M1 5 _ M1 8 _ M1 8 _ M1 8 _ M2 0 _ M2 0 _ M2 0 _ M2 2 _ A XEN XD0 XD1 XD1 XEN XD0 XD1 XEN XD0 XD1 XEN XD0 TXD1 TXEN R XD0 TXD1 TXD0 TXD1 R XD1 TXEN R XD0 TXD1 TXEN R XD0 TXD1 TXEN R XD0 R XD1 E M0 _ R M0 _ R M0 _ C M3 _ T M3 _ C M3 _ R M5 _ T M5 _ C M5 _ R M8 _ T M8 _ C M8 _ R M1 0 _ M1 0 _ M1 0 _ M1 3 _ M1 3 _ M1 3 _ M1 4 _ M1 6 R M1 5 _ M1 7 _ M1 7 _ M1 8 _ M2 0 _ M2 0 _ M2 0 _ M2 2 _ M2 2 _ AF XD1 XD0 R S XD0 R S XD1 XD0 R S XD1 XD0 R S XD1 TXD0 C R S R XD1 TXD0 C R S R XD1 C R S XD0 R XD1 R XD0 C R S R XD1 TXD0 C R S R XD1 R XD0 C R S A M1 _ T M1 _ T M1 _ T M2 _ T M2 _ C M4 _ T M4 _ C M6 _ T M6 _ C M7 _ T M7 _ C M9 _ T M9 _ C M1 1 _ M1 1 _ M1 2 _ M1 2 _ M1 4 _ M1 5 _ M1 6 _ M1 6 _ M1 8 _ M1 8 _ M1 9 _ M1 9 _ M2 1 _ M2 1 _ M2 2 _ M2 2 _ R S XD1 R S XD1 R S XD1 R S XD1 R S TXD1 C R S TXD1 C R S TXD1 TXD0 TXD1 C R S TXD0 C R S TXD1 C R S TXD1 C R S TXEN TXD0 G XEN XD0 XD1 XD1 M1 _ R M1 _ C M2 _ T M2 _ R M4 _ T M4 _ R M6 _ T M6 _ R M7 _ T M7 _ R M9 _ T M9 _ R M1 1 _ M1 1 _ M1 2 _ M1 2 _ M1 4 _ M1 4 _ M1 3 _ M1 5 _ M1 7 _ M1 7 _ M1 9 _ M1 9 _ M2 1 _ M2 1 _ M2 2 _ XD0 R S XD0 XD0 XD0 XD0 XD0 XD0 XD0 XD0 XD0 XD0 TXD0 R XD0 TXD0 R XD0 TXD0 R XD0 R XD0 C R S TXD0 R XD1 TXD0 R XD0 TXD0 R XD0 TXD1 A H M1 _ R M2 _ T M2 _ R M4 _ T M4 _ R M6 _ T M6 _ R M7 _ T M7 _ R M9 _ T M9 _ R M1 1 _ M1 1 _ M1 2 _ M1 2 _ M1 4 _ M1 4 _ M1 6 _ M1 3 _ M1 7 _ M1 7 _ M1 9 _ M1 9 _ M2 1 _ M2 1 _ XD1 XEN XD1 XEN XD1 XEN XD1 XEN XD1 XEN XD1 TXEN R XD1 TXEN R XD1 TXEN R XD1 TXEN TXEN TXEN TXD1 TXEN R XD1 TXEN R XD1 AJ 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Figure 19 - Power and Ground Distribution View 82 Zarlink Semiconductor Inc. 24 25 26 27 28 29 MVTX2603 Data Sheet 14.2 Ball – Signal Descriptions All pins are CMOS type; all Input Pins are 5 Volt tolerance; and all Output Pins are 3.3 CMOS drive. 14.2.1 Ball Signal Descriptions Ball Signal Descriptions Table Ball No(s) Symbol I/O Description C19, B19, A19, C20, B20, A20, C21, E20, B22, A22, C23, B23, A23, C24 B25 P_DATA[15:8][5:0 ] I/O with pull up Not used. Leave unconnected P_INT# Output Not used I2C Interface (0) Note: In unmanaged mode, Use I2C and Serial control interface to configure the system A24 SCL Output I2C Data Clock A25 SDA I/O-TS with pull up I2C Data I/O A26 STROBE Input with weak internal pull up Serial Strobe Pin B26 D0 Input Serial Data Input C25 AUTOFD Output with pull up Serial Data Output (AutoFD) D20, B21, D19, E19,D18, E18, D17, E17, D16, E16, D15, E15, D14, E14, D13, E13, D21, E21, A18, B18, C18, A17, B17, C17, A16, B16, C16, A15, B15, C15, A14, B14, D9, E9, D8, E8, D7, E7, D6, E6, D5, E5, D4, E4, D3, E3, D2, E2, A7, B7, A6, B6, C6, A5, B5, C5, A4, B4, C4, A3, B3, C3, B2, C2 LA_D[63:0] I/O-TS with pull up Frame Bank A– Data Bit [63:0] C14, A13, B13, C13, A12, B12, C12, A11, B11, C11, D11, E11, A10, B10, D10, E10, A8, C7 LA_A[20:3] Output Frame Bank A – Address Bit [20:3] B8 LA_ADSC# Output with pull up Frame Bank Control C1 LA_CLK Output Frame Bank A Clock Input C9 LA_WE# Output with pull up Frame Bank A Write Chip Select for one layer SRAM application D12 LA_WE0# Output with pull up Frame Bank A Write Chip Select for lower layer of two layers SRAM application Serial Control Interface Frame Buffer Interface Zarlink Semiconductor Inc. A Address Status 83 MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) E12 LA_WE1# Output with pull up Frame Bank A Write Chip Select for upper layer of two layers SRAM application C8 LA_OE# Output with pull up Frame Bank A Read Chip Select for one layer SRAM application A9 LA_OE0# Output with pull up Frame Bank A Read Chip Select for lower layer of two layers SRAM application B9 LA_OE1# Output with pull up Frame Bank A Read Chip Select for upper layer of two layers SRAM application F4, F5, G4, G5, H4, H5, J4, J5, K4, K5, L4, L5, M4, M5, N4, N5, G3, H1, H2, H3, J1, J2, J3, K1, K2, K3, L1, L2, L3, M1, M2, M3, U4, U5, V4, V5, W4, W5, Y4, Y5, AA4, AA5, AB4, AB5, AC4, AC5, AD4, AD5, W1, Y1, Y2, Y3, AA1, AA2, AA3, AB1, AB2, AB3, AC1, AC2, AC3, AD1, AD2, AD3 LB_D[63:0] I/O-TS with pull up. Frame Bank B– Data Bit [63:0] N3, N2, N1, P3, P2, P1, R5, R4, R3, R2, R1, T5, T4, T3, T2, T1, W3, W2 LB_A[20:3] Output Frame Bank B – Address Bit [20:3] V1 LB_ADSC# Output with pull up Frame Bank Control G1 LB_CLK Output Frame Bank B Clock Input V3 LB_WE# Output with pull up Frame Bank B Write Chip Select for one layer SRAM application P4 LB_WE0# Output with pull up Frame Bank B Write Chip Select for lower layer of two layers SRAM application P5 LB_WE1# Output with pull up Frame Bank B Write Chip Select for upper layer of two layers SRAM application V2 LB_OE# Output with pull up Frame Bank B Read Chip Select for one layer SRAM application U1 LB_OE0# Output with pull up Frame Bank B Write Chip Select for lower layer of two layers SRAM application U2 LB_OE1# Output with pull up Frame Bank B Write Chip Select for upper layer of two layers SRAM application Output MII Management Data Clock – (Common for all MII Ports [23:0]) B Address Status Fast Ethernet Access Ports [23:0] RMII R28 84 M_MDC Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) P28 M_MDIO I/O-TS with pull up MII Management Data I/O – (Common for all MII Ports –[23:0])) R29 M_CLKI Input Reference Input Clock AC29, AE28, AJ27, AF27, AJ25, AF24, AH23, AE19, AF21, AJ19, AF18, AJ17, AJ15, AF15, AJ13, AF12, AJ11, AJ9, AF9, AJ7, AF6, AJ5, AJ3, AF1 M[23:0]_RXD[1] Input with weak internal pull up resistors. Ports [23:0] – Receive Data Bit [1] AC28, AF28, AH27, AE27, AH25, AE24, AF22, AF20, AE21, AH19, AH20, AH17, AH15, AE15, AH13, AE12, AH11, AH9, AE9, AH7, AE6, AH5, AH2, AF2 M[23:0]_RXD[0] Input with weak internal pull up resistors Ports [23:0] – Receive Data Bit [0] AC27, AF29, AG27, AF26, AG25, AG23, AF23, AG21, AH21, AF19, AF17, AG17, AG15, AF14, AG13, AF11, AG11, AG9, AF8, AG7, AF5, AG5, AH3, AF3 M[23:0]_CRS_DV Input with weak internal pull down resistors. Ports [23:0] – Carrier Sense and Receive Data Valid AD29, AG28, AJ26, AE26, AJ24, AE23, AJ22, AJ20, AE20, AJ18, AJ21, AJ16, AJ14, AE14, AJ12, AE11, AJ10, AJ8, AE8, AJ6, AE5, AJ4, AG1, AE1 M[23:0]_TXEN I/O- TS with pull up, slew Ports [23:0] – Transmit Enable AD27, AH28, AG26, AE25, AG24, AE22, AJ23, AG20, AE18, AG18, AE16, AG16, AG14, AE13, AG12, AE10, AG10, AG8, AE7, AG6, AE4, AG4, AG3, AE3 M[23:0]_TXD[1] Output, slew Ports [23:0] – Transmit Data Bit [1] AD28, AG29, AH26, AF25, AH24, AG22, AH22, AE17, AG19, AH18, AF16, AH16, AH14, AF13, AH12, AF10, AH10, AH8, AF7, AH6, AF4, AH4, AG2, AE2 M[23:0]_TXD[0] Output, slew Ports [23:0] – Transmit Data Bit [0] Strap option for RMII/GPSI GMII Gigabit Ethernet Access Ports 0 & 1 U26, U25, V26, V25, W26, W25, Y27, Y26, AA26, AA25, AB26, AB25, AC26, AC25, AD26, AD25 M25_TXD[15:0] Output Transmit Data Bit [15:0] T28 M25_RX_DV Input w/ pull down Receive Data Valid U28 M25_RX_ER Input w/ pull up Receive Error Zarlink Semiconductor Inc. 85 MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) R25 M25_CRS Input w/ pull down Carrier Sense U29 M25_COL Input w/ pull up Collision Detected T29 M25_RXCLK Input w/ pull up Receive Clock U27, V29, V28, V27, W29, W28, W27, Y29, Y28, Y25, AA29, AA28, AA27, AB29, AB28, AB27 M25_RXD[15:0] Input w/ pull up Receive Data Bit [15:0] T26 M25_TX_EN Output w/ pull up Transmit Data Enable R26 M25_TX_ER Output w/ pull up Transmit Error T25 M25_ TXCLK Output Gigabit Transmit Clock P29 GREF_CLK0 Input w/ pull up Gigabit Reference Clock G26, G25, H26, H25, J26, J25, K25, K26, M25, L26, M26, L25, N26, N25, P26, P25 M26_TXD[15:0] Output Transmit Data Bit [15:0] F28 M26_RX_DV Input w/ pull down Receive Data Valid G28 M26_RX_ER Input w/ pull up Receive Error E25 M26_CRS Input w/ pull down Carrier Sense G29 M26_COL Input w/ pull up Collision Detected F29 M26_RXCLK Input w/ pull up Receive Clock G27,H29, H28, H27, J29, J28, J27, K29, K28, K27, L29, L28, L27, M29, M28, M27 M26_RXD[15:0] Input w/ pull up Receive Data Bit [15:0] F26 M26_TX_EN Output w/ pull up Transmit Data Enable E26 M26_TX_ER Output w/ pull up Transmit Error F25 M26_ TXCLK Output Gigabit Transmit Clock N29 GREF_CLK1 Input w/ pull up Gigabit Reference Clock C29 LED_CLK/TSTOU T0 I/O- TS with pull up LED Serial Interface Output Clock D29 LED_SYN/TSTO UT1 I/O- TS with pull up LED Output Data Stream Envelope E29 LED_BIT/TSTOU T2 I/O- TS with pull up LED Serial Data Output Stream B28 G1_RXTX#/TSTO UT3 I/O- TS with pull up LED for Gigabit port 1 (receive + transmit) C28 G1_DPCOL#/TST OUT4 I/O- TS with pull up LED for Gigabit port 1 (full duplex + collision) LED Interface 86 Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) D28 G1_LINK#/TSTO UT5 I/O- TS with pull up LED for Gigabit port 1 E28 G2_RXTX#/TSTO UT6 I/O- TS with pull up LED for Gigabit port 2 (receive + transmit) A27 G2_DPCOL#/TST OUT7 I/O- TS with pull up LED for Gigabit port 2 (full duplex + collision) B27 G2_LINK#/TSTO UT8 I/O- TS with pull up LED for Gigabit port 2 C27 INIT_DONE/TST OUT9 I/O- TS with pull up System start operation D27 INIT_START/TST OUT10 I/O- TS with pull up Start initialization C26 CHECKSUM_OK/ TSTOUT11 I/O- TS with pull up EEPROM read OK D26 FCB_ERR/TSTO UT12 I/O- TS with pull up FCB memory self test fail D25 MCT_ERR/TSTO UT13 I/O- TS with pull up MCT memory self test fail D24 BIST_IN_PRC/TS TOUT14 I/O- TS with pull up Processing memory self test E24 BIST_DONE/TST OUT15 I/O- TS with pull up Memory self test done C22 TRUNK0 Input w/ weak internal pull down resistors Trunk Port Enable A21 TRUNK1 Input w/ weak internal pull down resistors Trunk Port Enable B24 TRUNK2 Input w/ weak internal pull down resistors Trunk Port Enable T_MODE0 I/O-TS Test Pin – Set Mode upon Reset, and provides NAND Tree test output during test mode (Pull Up) Trunk Enable Test Facility U3 Zarlink Semiconductor Inc. 87 MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) C10 T_MODE1 I/O-TS Test Pin – Set Mode upon Reset, and provides NAND Tree test output during test mode (Pull Up) T_MODE1 0 0 1 1 T_MODE0 0 NandTree 1 Reserved 0 Reserved 1 Regular operation T_MODE0 and T_MODE1 are used for manufacturing tests. The signals should both be set to 1 for regular operation. F3 SCAN_EN Input with pull down Scan Enable 0 - Normal mode (unconnected) E27 SCANMODE Input with pull down 1 - Enables Test mode. 0 - Normal mode (unconnected) System Clock, Power, and Ground Pins E1 SCLK Input System Clock at 100 MHz K12, K13, K17,K18 M10, N10, M20, N20, U10, V10, U20, V20, Y12, Y13, Y17, Y18 VDD Power +2.5 Volt DC Supply F13, F14, F15, F16, F17, N6, P6, R6, T6, U6, N24, P24, R24, T24, U24, AD13, AD14, AD15, AD16, AD17 VDD33 Power +3.3 Volt DC Supply M12, M13, M14, M15, M16, M17, M18, N12, N13, N14, N15, N16, N17, N18, P12, P13, P14, P15, P16, P17, P18, R12, R13, R14, R15, R16, R17, R18, T12, T13, T14, T15, T16, T17, T18, U12, U13, U14, U15, U16, U17, U18, V12, V13, V14, V15, V16, V17, V18, VSS Power Ground Ground F1 AVCC Analog Power Used for the PLL D1 AGND Analog Ground Used for the PLL D22 SCANCOL Input Scans the Collision signal of Home PHY D23 SCANCLK Input/ output Clock for scanning Home PHY collision and link MISC 88 Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) E23 SCANLINK Input Link up signal from Home PHY F2 RESIN# Input Reset Input G2 RESETOUT_ Output Reset PHY B22 Reserved I/O-TS Reserved Bootstrap Pins (Default= pull up, 1= pull up 0= pull down) After reset TSTOUT0 to TSTOUT15 are used by the LED interface. C29 TSTOUT0 Default: Active High (1) GIGA Link polarity 0 - Active low 1 - Active high D29 TSTOUT1 Default: Enable (1) RMII MAC Power Saving Enable 0 - No power saving 1 - Power saving E29 TSTOUT2 Default: (1) B28 TSTOUT3 Default: Disable Swap (1) Must be 0. Use external pull down Hot Module detect enable 0 - Hot swap enable 1 - Hot swap disable C28 TSTOUT4 Default: SBRAM (1) Memory is SBRAM/ZBT 0 - ZBT 1 – Pipeline SBRAM D28 TSTOUT5 Default: SCLK (1) Scan Speed 0 - ¼ SCLK(HPNA) 1 - SCLK E28 TSTOUT6 Default: (1) Reserved A27 TSTOUT7 Default: 128K x 32 or 128K x 64 (1) Memory Size 0 - 256K x 32 or 256K x 64 (4M total) 1 - 128K x 32 or 128K x 64 (2M total) B27 TSTOUT8 Default: Not Installed (1) EEPROM Installed 0 - EEPROM installed 1 - EEPROM not installed C27 TSTOUT9 Default: MCT enable (1) aging MCT Aging 0 - MCT aging disable 1 - MCT aging enable Zarlink Semiconductor Inc. 89 MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) D27 TSTOUT10 Default: FCB enable (1) aging FCB Aging 0 - FCB aging disable 1 - FCB aging enable C26 TSTOUT11 Default: Timeout reset enable (1) Timeout Reset 0 - Time out reset disable 1 - Time out reset enable. Issue reset if any state machine did not go back to idle for 5 Sec. D26 TSTOUT12 Default: Normal (1) Test Speed Up 0 - Enable test speed up. Do not use. 1 - Disable test speed up D25 TSTOUT13 Default: Single depth (1) FDB RAM depth (1 or 2 layers) 0 - Two layers 1 - One layer D24 TSTOUT14 Default: (1) E24 TSTOUT15 Default: operation Reserved. Leave unconnected Normal SRAM Test Mode 0 - Enable test mode 1 - Normal operation T26 G0_TXEN Default: PCS Giga0 Mode: G0_TXEN G0_TXER 0 0 0 1 1 0 1 1 R26 G0_TXER Default: PCS F26 G1_TXEN Default: PCS MII 2G GMII PCS Giga0 Mode: G1_TXEN G1_TXER 0 0 MII 0 1 2G 1 0 GMII 1 1 PCS 90 E26 G1_TXER Default: PCS AD29, AG28, AJ26, AE26, AJ24, AE23, AJ22, AJ20, AE20, AJ18, AJ21, AJ16, AJ14, AE14, AJ12, AE11, AJ10, AJ8, AE8, AJ6, AE5, AJ4, AG1, AE1, M[23:0]_TXEN Default: RMII 0 – GPSI 1 - RMII Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball Signal Descriptions Table (continued) P_D[9] C21 Default: PLL Enable PLL enable LB_CLK. for LA_CLK and 0 – Disable PLL, Use delay specified by P_D[15:10] strap option 1 – Enable PLL P_D[15:13] C19, B19, A19 Default: 111 Programmable delay for internal OE_CLK from SCLK input when PLL is disabled. The OE_CLK is used for generating the OE0 and OE1 signals Suggested value is 001. P_D[12:10] C20, B20, A20 Default: 111 Programmable delay for LA_CLK and LB_CLK from internal OE_CLK when PLL is disabled. The LA_CLK and LB_CLK delay from SCLK is the sum of the delay programmed in here and the delay in P_D[15:13]. Suggested value is 011. Notes: 14.3 #= Active low signal Input = Input signal In-ST = Input signal with Schmitt-Trigger Output = Output signal (Tri-State driver) Out-OD= Output signal with Open-Drain driver I/O-TS = Input & Output signal with Tri-State driver I/O-OD = Input & Output signal with Open-Drain driver Ball – Signal Name Ball – Signal Name Table Ball No. Signal Name Ball No. Signal Name Signal Name Ball No. D20 LA_D[63] D3 LA_D[19] A9 LA_OE0# B21 LA_D[62] E3 LA_D[18] B9 LA_OE1# D19 LA_D[61] D2 LA_D[17] F4 LB_D[63] E19 LA_D[60] E2 LA_D[16] F5 LB_D[62] D18 LA_D[59] A7 LA_D[15] G4 LB_D[61] E18 LA_D[58] B7 LA_D[14] G5 LB_D[60] D17 LA_D[57] A6 LA_D[13] H4 LB_D[59] Zarlink Semiconductor Inc. 91 MVTX2603 Data Sheet Ball – Signal Name Table (continued) Ball No. 92 Signal Name Ball No. Signal Name Signal Name Ball No. E17 LA_D[56] B6 LA_D[12] H5 LB_D[58] D16 LA_D[55] C6 LA_D[11] J4 LB_D[57] E16 LA_D[54] A5 LA_D[10] J5 LB_D[56] D15 LA_D[53] B5 LA_D[9] K4 LB_D[55] E15 LA_D[52] C5 LA_D[8] K5 LB_D[54] D14 LA_D[51] A4 LA_D[7] L4 LB_D[53] E14 LA_D[50] B4 LA_D[6] L5 LB_D[52] D13 LA_D[49] C4 LA_D[5] M4 LB_D[51] E13 LA_D[48] A3 LA_D[4] M5 LB_D[50] D21 LA_D[47] B3 LA_D[3] N4 LB_D[49] E21 LA_D[46] C3 LA_D[2] N5 LB_D[48] A18 LA_D[45] B2 LA_D[1] G3 LB_D[47] B18 LA_D[44] C2 LA_D[0] H1 LB_D[46] C18 LA_D[43] C14 LA_A[20] H2 LB_D[45] A17 LA_D[42] A13 LA_A[19] H3 LB_D[44] B17 LA_D[41] B13 LA_A[18] J1 LB_D[43] C17 LA_D[40] C13 LA_A[17] J2 LB_D[42] A16 LA_D[39] A12 LA_A[16] J3 LB_D[41] B16 LA_D[38] B12 LA_A[15] K1 LB_D[40] C16 LA_D[37] C12 LA_A[14] K2 LB_D[39] A15 LA_D[36] A11 LA_A[13] K3 LB_D[38] B15 LA_D[35] B11 LA_A[12] L1 LB_D[37] C15 LA_D[34] C11 LA_A[11] L2 LB_D[36] A14 LA_D[33] D11 LA_A[10] L3 LB_D[35] B14 LA_D[32] E11 LA_A[9] M1 LB_D[34] D9 LA_D[31] A10 LA_A[8] M2 LB_D[33] E9 LA_D[30] B10 LA_A[7] M3 LB_D[32] D8 LA_D[29] D10 LA_A[6] U4 LB_D[31] E8 LA_D[28] E10 LA_A[5] U5 LB_D[30] D7 LA_D[27] A8 LA_A[4] V4 LB_D[29] Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball – Signal Name Table (continued) Ball No. Signal Name Ball No. Signal Name Signal Name Ball No. E7 LA_D[26] C7 LA_A[3] V5 LB_D[28] D6 LA_D[25] B8 LA_ADSC# W4 LB_D[27] E6 LA_D[24] C1 LA_CLK W5 LB_D[26] D5 LA_D[23] C9 LA_WE# Y4 LB_D[25] E5 LA_D[22] D12 LA_WE0# Y5 LB_D[24] D4 LA_D[21] E12 LA_WE1# AA4 LB_D[23] E4 LA_D[20] C8 LA_OE# AA5 LB_D[22] AB4 LB_D[21] U2 LB_OE1# AH7 M[4]_RXD[0] AB5 LB_D[20] R28 MDC AE6 M[3]_RXD[0] AC4 LB_D[19] P28 MDIO AH5 M[2]_RXD[0] AC5 LB_D[18] R29 M_CLK AH2 M[1]_RXD[0] AD4 LB_D[17] AC29 M[23]_RXD[1] AF2 M[0]_RXD[0] AD5 LB_D[16] AE28 M[22]_RXD[1] AC27 M[23]_CRS_DV W1 LB_D[15] AJ27 M[21]_RXD[1] AF29 M[22]_CRS_DV Y1 LB_D[14] AF27 M[20]_RXD[1] AG27 M[21]_CRS_DV Y2 LB_D[13] AJ25 M[19]_RXD[1] AF26 M[20]_CRS_DV Y3 LB_D[12] AF24 M[18]_RXD[1] AG25 M[19]_CRS_DV AA1 LB_D[11] AH23 M[17]_RXD[1] AG23 M[18]_CRS_DV AA2 LB_D[10] AE19 M[16]_RXD[1] AF23 M[17]_CRS_DV AA3 LB_D[9] AF21 M[15]_RXD[1] AG21 M[16]_CRS_DV AB1 LB_D[8] AJ19 M[14]_RXD[1] AH21 M[15]_CRS_DV AB2 LB_D[7] AF18 M[13]_RXD[1] AF19 M[14]_CRS_DV AB3 LB_D[6] AJ17 M[12]_RXD[1] AF17 M[13]_CRS_DV AC1 LB_D[5] AJ15 M[11]_RXD[1] AG17 M[12]_CRS_DV AC2 LB_D[4] AF15 M[10]_RXD[1] AG15 M[11]_CRS_DV AC3 LB_D[3] AJ13 M[9]_RXD[1] AF14 M[10]_CRS_DV AD1 LB_D[2] AF12 M[8]_RXD[1] AG13 M[9]_CRS_DV AD2 LB_D[1] AJ11 M[7]_RXD[1] AF11 M[8]_CRS_DV AD3 LB_D[0] AJ9 M[6]_RXD[1] AG11 M[7]_CRS_DV N3 LB_A[20] AF9 M[5]_RXD[1] AG9 M[6]_CRS_DV Zarlink Semiconductor Inc. 93 MVTX2603 Data Sheet Ball – Signal Name Table (continued) Ball No. 94 Signal Name Ball No. Signal Name Signal Name Ball No. N2 LB_A[19] AJ7 M[4]_RXD[1] AF8 M[5]_CRS_DV N1 LB_A[18] AF6 M[3]_RXD[1] AG7 M[4]_CRS_DV P3 LB_A[17] AJ5 M[2]_RXD[1] AF5 M[3]_CRS_DV P2 LB_A[16] AJ3 M[1]_RXD[1] AG5 M[2]_CRS_DV P1 LB_A[15] AF1 M[0]_RXD[1] AH3 M[1]_CRS_DV R5 LB_A[14] AC28 M[23]_RXD[0] AF3 M[0]_CRS_DV R4 LB_A[13] AF28 M[22]_RXD[0] AD29 M[23]_TXEN R3 LB_A[12] AH27 M[21]_RXD[0] AG28 M[22]_TXEN R2 LB_A[11] AE27 M[20]_RXD[0] AJ26 M[21]_TXEN R1 LB_A[10] AH25 M[19]_RXD[0] AE26 M[20]_TXEN T5 LB_A[9] AE24 M[18]_RXD[0] AJ24 M[19]_TXEN T4 LB_A[8] AF22 M[17]_RXD[0] AE23 M[18]_TXEN T3 LB_A[7] AF20 M[16]_RXD[0] AJ22 M[17]_TXEN T2 LB_A[6] AE21 M[15]_RXD[0] AJ20 M[16]_TXEN T1 LB_A[5] AH19 M[14]_RXD[0] AE20 M[15]_TXEN W3 LB_A[4] AH20 M[13]_RXD[0] AJ18 M[14]_TXEN W2 LB_A[3] AH17 M[12]_RXD[0] AJ21 M[13]_TXEN V1 LB_ADSC# AH15 M[11]_RXD[0] AJ16 M[12]_TXEN G1 LB_CLK AE15 M[10]_RXD[0] AJ14 M[11]_TXEN V3 LB_WE# AH13 M[9]_RXD[0] AE14 M[10]_TXEN P4 LB_WE0# AE12 M[8]_RXD[0] AJ12 M[9]_TXEN P5 LB_WE1# AH11 M[7]_RXD[0] AE11 M[8]_TXEN V2 LB_OE# AH9 M[6]_RXD[0] AJ10 M[7]_TXEN U1 LB_OE0# AE9 M[5]_RXD[0] AJ8 M[6]_TXEN AE8 M[5]_TXEN AH8 M[6]_TXD[0] G27 M26_RXD[15] AJ6 M[4]_TXEN AF7 M[5]_TXD[0] H29 M26_RXD[14] AE5 M[3]_TXEN AH6 M[4]_TXD[0] H28 M26_RXD[13] AJ4 M[2]_TXEN AF4 M[3]_TXD[0] H27 M26_RXD[12] AG1 M[1]_TXEN AH4 M[2]_TXD[0] J29 M26_RXD[11] AE1 M[0]_TXEN AG2 M[1]_TXD[0] J28 M26_RXD[10] Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball – Signal Name Table (continued) Ball No. Signal Name Ball No. Signal Name Signal Name Ball No. AD27 M[23]_TXD[1] AE2 M[0]_TXD[0] J27 M26_RXD[9] AH28 M[22]_TXD[1] U26 M25_TXD[15] K29 M26_RXD[8] AG26 M[21]_TXD[1] U25 M25_TXD[14] K28 M26_RXD[7] AE25 M[20]_TXD[1] V26 M25_TXD[13] K27 M26_RXD[6] AG24 M[19]_TXD[1] V25 M25_TXD[12] L29 M26_RXD[5] AE22 M[18]_TXD[1] W26 M25_TXD[11] L28 M26_RXD[4] AJ23 M[17]_TXD[1] W25 M25_TXD[10] L27 M26_RXD[3] AG20 M[16]_TXD[1] Y27 M25_TXD[9] M29 M26_RXD[2] AE18 M[15]_TXD[1] Y26 M25_TXD[8] M28 M26_RXD[1] AG18 M[14]_TXD[1] AA26 M25_TXD[7] M27 M26_RXD[0] AE16 M[13]_TXD[1] AA25 M25_TXD[6] G26 M26_TXD[15] AG16 M[12]_TXD[1] AB26 M25_TXD[5] G25 M26_TXD[14] AG14 M[11]_TXD[1] AB25 M25_TXD[4] H26 M26_TXD[13] AE13 M[10]_TXD[1] AC26 M25_TXD[3] H25 M26_TXD[12] AG12 M[9]_TXD[1] AC25 M25_TXD[2] J26 M26_TXD[11] AE10 M[8]_TXD[1] AD26 M25_TXD[1] J25 M26_TXD[10] AG10 M[7]_TXD[1] AD25 M25_TXD[0] K25 M26_TXD[9] AG8 M[6]_TXD[1] U27 M25_RXD[15] K26 M26_TXD[8] AE7 M[5]_TXD[1] V29 M25_RXD[14] M25 M26_TXD[7] AG6 M[4]_TXD[1] V28 M25_RXD[13] L26 M26_TXD[6] AE4 M[3]_TXD[1] V27 M25_RXD[12] M26 M26_TXD[5] AG4 M[2]_TXD[1] W29 M25_RXD[11] L25 M26_TXD[4] AG3 M[1]_TXD[1] W28 M25_RXD[10] N26 M26_TXD[3] AE3 M[0]_TXD[1] W27 M25_RXD[9] N25 M26_TXD[2] AD28 M[23]_TXD[0] Y29 M25_RXD[8] P26 M26_TXD[1] AG29 M[22]_TXD[0] Y28 M25_RXD[7] P25 M26_TXD[0] AH26 M[21]_TXD[0] Y25 M25_RXD[6] F28 M26_RX_DV AF25 M[20]_TXD[0] AA29 M25_RXD[5] G28 M26_RX_ER AH24 M[19]_TXD[0] AA28 M25_RXD[4] E25 M26_CRS AG22 M[18]_TXD[0] AA27 M25_RXD[3] G29 M26_COL Zarlink Semiconductor Inc. 95 MVTX2603 Data Sheet Ball – Signal Name Table (continued) Ball No. 96 Signal Name Ball No. Signal Name Signal Name Ball No. AH22 M[17]_TXD[0] AB29 M25_RXD[2] F29 M26_RXCLK AE17 M[16]_TXD[0] AB28 M25_RXD[1] F26 M26_TX_EN AG19 M[15]_TXD[0] AB27 M25_RXD[0] E26 M26_TX_ER AH18 M[14]_TXD[0] R26 M25_TX_ER F25 M26_TXCLK AF16 M[13]_TXD[0] T25 M25_TXCLK E24 BIST_DONE/TSTOUT[15] AH16 M[12]_TXD[0] T26 M25_TX_EN D24 BIST_IN_PRC/TST0UT[14] AH14 M[11]_TXD[0] T28 M25_RX_DV D25 MCT_ERR/TSTOUT[13] AF13 M[10]_TXD[0] U28 M25_RX_ER D26 FCB_ERR/TSTOUT[12] AH12 M[9]_TXD[0] R25 M25_CRS C26 CHECKSUM_OK/TSTOUT[11] AF10 M[8]_TXD[0] U29 M25_COL D27 INIT_START/TSTOUT[10] AH10 M[7]_TXD[0] T29 M25_RXCLK C27 INIT_DONE/TSTOUT[9] B27 G2_LINK#/TSTOUT[8] U18 VSS N12 VSS A27 G2_DPCOL#/TSTOUT[7] V12 VSS N13 VSS E28 G2_RXTX#/TSTOUT[6] V13 VSS K17 VDD D28 G1_LINK#/TSTOUT[5] V14 VSS K18 VDD C28 G1_DPCOL#/TSTOUT[4] V15 VSS M10 VDD B28 G1_RXTX#/TSTOUT[3] V16 VSS N10 VDD E29 LED_BIT/TSTOUT[2] V17 VSS M20 VDD D29 LED_SYN/TSTOUT[1] V18 VSS N20 VDD C29 LED_CLK/TSTOUT[0] N14 VSS U10 VDD N29 GREF_CLK1 N15 VSS V10 VDD P29 GREF_CLK0 N16 VSS U20 VDD F3 SCAN_EN N17 VSS V20 VDD E1 SCLK N18 VSS Y12 VDD U3 T_MODE0 P12 VSS Y13 VDD C10 T_MODE1 P13 VSS Y17 VDD B24 TRUNK2 P14 VSS Y18 VDD A21 TRUNK1 P15 VSS K12 VDD C22 TRUNK0 P16 VSS K13 VDD A26 STROBE C19 RESERVED M16 VSS Zarlink Semiconductor Inc. MVTX2603 Data Sheet Ball – Signal Name Table (continued) Ball No. Signal Name Ball No. Signal Name Signal Name Ball No. B26 D0 B19 RESERVED M17 VSS C25 AUTOFD A19 RESERVED M18 VSS A24 SCL R13 VSS F16 VDD33 A25 SDA R14 VSS F17 VDD33 F1 AVCC R15 VSS N6 VDD33 D1 AGND R16 VSS P6 VDD33 D22 SCANCOL R17 VSS R6 VDD33 E23 SCANLINK R18 VSS T6 VDD33 E27 SCANMODE T12 VSS U6 VDD33 N28 T13 VSS N24 VDD33 N27 T14 VSS P24 VDD33 F2 RESIN# T15 VSS R24 VDD33 G2 RESETOUT_ T16 VSS T24 VDD33 B22 RESERVED T17 VSS U24 VDD33 A22 RESERVED T18 VSS AD13 VDD33 C23 RESERVED U12 VSS AD14 VDD33 B23 RESERVED U13 VSS AD15 VDD33 A23 RESERVED U14 VSS AD16 VDD33 C24 RESERVED U15 VSS AD17 VDD33 D23 SCANCLK U16 VSS F13 VDD33 T27 M25_MTXCLK U17 VSS F14 VDD33 F27 M26_MTXCLK M12 VSS F15 VDD33 C20 RESERVED M13 VSS R12 VSS B20 RESERVED M14 VSS B25 RESERVED A20 RESERVED M15 VSS E20 RESERVED C21 RESERVED P17 VSS P18 VSS 14.4 AC/DC Timing 14.4.1 Absolute Maximum Ratings Storage Temperature -65°C to +150°C Zarlink Semiconductor Inc. 97 MVTX2603 Data Sheet Operating Temperature -40°C to +85°C Supply Voltage VDD33 with Respect to VSS +3.0 V to +3.6 V Supply Voltage VDD with Respect to VSS +2.38 V to +2.75 V Voltage on Input Pins -0.5 V to (VDD33 + 0.3 V) Caution: Stress above those listed may damage the device. Exposure to the Absolute Maximum Ratings for extended periods may affect device reliability. Functionality at or above these limits is not implied. 14.4.2 DC Electrical Characteristics VDD33 = 3.0 V to 3.6 V (3.3v +/- 10%) TAMBIENT = -40°C to +85°C VDD = 2.5V +10% - 5% 14.4.3 Recommended Operation Conditions Recommended Operation Conditions Table Preliminary Symbol Parameter Description Min Max 100 Unit fosc Frequency of Operation IDD1 Supply Current – @ 100 MHz (VDD33 =3.3 V) 450 mA IDD2 Supply Current – @ 100 MHz (VDD =2.5 V) 1500 mA VOH Output High Voltage (CMOS) MHz VOL Output Low Voltage (CMOS) VIH-TTL Input High Voltage (TTL 5V tolerant) VIL-TTL VDD33 - 0.5 V 0.5 V VDD33 + 2.0 V Input Low Voltage (TTL 5V tolerant) VDD33 x 30% V IIH-5VT Input Leakage Current (0.1 V < VIN < VDD33) (all pins except those with internal pull-up/pull-down resistors) 10 µA CIN Input Capacitance 5 pF COUT Output Capacitance 5 pF CI/O I/O Capacitance 7 pF θja Thermal resistance with 0 air flow 11.2 C/W θja Thermal resistance with 1 m/s air flow 10.2 C/W θja Thermal resistance with 2m/s air flow 8.9 C/W 14.5 Local Frame Buffer SBRAM Memory Interface 14.5.1 Local SBRAM Memory Interface 98 Typ Zarlink Semiconductor Inc. VDD33 x 70% MVTX2603 Data Sheet LA_CLK L1 LA_D[63:0] L2 Figure 20 - Local Memory Interface – Input setup and hold timing LA_CLK LA_D[63:0] LA_A[20:3] LA_ADSC# LA_WE[1:0]# #### LA_OE[1:0]# LA_WE# LA_OE# L3-max L3-min L4-max L4-min L6-max L6-min L7-max L7-min L8-max L8-min L9-max L9-min L10-max L10-min Figure 21 - Local Memory Interface - Output valid delay timing Zarlink Semiconductor Inc. 99 MVTX2603 Data Sheet -100MHz Symbol Parameter Min (ns) Max (ns) Note L1 LA_D[63:0] input set-up time 4 L2 LA_D[63:0] input hold time 1.5 L3 LA_D[63:0] output valid delay 1.5 7 CL = 25pf L4 LA_A[20:3] output valid delay 2 7 CL = 30pf L6 LA_ADSC# output valid delay 1 7 CL = 30pf L7 LA_WE[1:0]#output valid delay 1 7 CL = 25pf L8 LA_OE[1:0]# output valid delay -1 1 CL = 25pf L9 LA_WE# output valid delay 1 7 CL = 25pf L10 LA_OE# output valid delay 1 5 CL = 25pf Table 13 - AC Characteristics – Local frame buffer SBRAM Memory Interface 14.6 Local Switch Database SBRAM Memory Interface 14.6.1 Local SBRAM Memory Interface: LB_CLK L1 LB_D[63:0] L2 Figure 22 - Local Memory Interface – Input setup and hold timing 100 Zarlink Semiconductor Inc. MVTX2603 Data Sheet LB_CLK LB_D[31:0] LB_A[21:2] LB_ADSC# LB_WE[1:0]# LB_OE[1:0]# L3-max L3-min L4-max L4-min L6-max L6-min L8-max L8-min L9-max L9-min L10-max L10-min LB_WE# L11-max L11-min LB_OE# Figure 23 - Local Memory Interface - Output valid delay timing -100MHz Symbol Parameter Min (ns) Max (ns) Note L1 LB_D[63:0] input set-up time 4 L2 LB_D[63:0] input hold time 1.5 L3 LB_D[63:0] output valid delay 1.5 7 CL = 25pf L4 LB_A[20:3] output valid delay 2 7 CL = 30pf L6 LB_ADSC# output valid delay 1 7 CL = 30pf L8 LB_WE[1:0]#output valid delay 1 7 CL = 25pf L9 LB_OE[1:0]# output valid delay -1 1 CL = 25pf L10 LB_WE# output valid delay 1 7 CL = 25pf L11 LB_OE# output valid delay 1 5 CL = 25pf Table 14 - AC Characteristics – Local Switch Database SBRAM Memory Interface Zarlink Semiconductor Inc. 101 MVTX2603 Data Sheet 14.7 AC Characteristics 14.7.1 Reduced Media Independent Interface M_CLKI M6-max M6-min M[23:0]_TXEN M7-max M7-min M[23:0] _TXD[1:0] Figure 24 - AC Characteristics – Reduced Media Independent Interface M_CLKI M[23:0]_RXD M2 M3 M[23:0]_CRS_DV M4 M5 Figure 25 - AC Characteristics – Reduced Media Independent Interface -50MHz Symbol Parameter Note Min (ns) Max (ns) M2 M[23:0]_RXD[1:0] Input Setup Time 4 M3 M[23:0]_RXD[1:0] Input Hold Time 1 M4 M[23:0]_CRS_DV Input Setup Time 4 M5 M[23:0]_CRS_DV Input Hold Time 1 M6 M[23:0]_TXEN Output Delay Time 2 11 CL = 20 pF M7 M[23:0]_TXD[1:0] Output Delay Time 2 11 CL = 20 pF Table 15 - AC Characteristics – Reduced Media Independent Interface 102 Zarlink Semiconductor Inc. MVTX2603 Data Sheet M25_TXCLK M25_TXD [15:0] M25_TX_EN] M25_TX_ER G12-max G12-min G13-max G13-min G14-max G14-min Figure 26 - AC Characteristics- GMII M25_RXCLK G1 G2 M25_RXD[15:0] G3 G4 M25_RX_DV G5 G6 M25_RX_ER G7 G8 M25_RX_CRS Figure 27 - AC Characteristics – Gigabit Media Independent Interface -125Mhz Symbol Parameter Note Min (ns) G1 M[25]_RXD[15:0] Input Setup Times 2 G2 M[25]_RXD[15:0] Input Hold Times 1 G3 M[25]_RX_DV Input Setup Times 2 G4 M[25]_RX_DV Input Hold Times 1 G5 M[25]_RX_ER Input Setup Times 2 G6 M[25]_RX_ER Input Hold Times 1 G7 M[25]_CRS Input Setup Times 2 G8 M[25]_CRS Input Hold Times 1 Max (ns) Figure 28 - AC Characteristics – Gigabit Media Independent Interface Zarlink Semiconductor Inc. 103 MVTX2603 Data Sheet -125Mhz Symbol Parameter Note Min (ns) Max (ns) G12 M[25]_TXD[15:0] Output Delay Times 1 6 CL = 20pf G13 M[25]_TX_EN Output Delay Times 1 6.5 CL = 20pf G14 M[25]_TX_ER Output Delay Times 1 6 CL = 20pf Figure 28 - AC Characteristics – Gigabit Media Independent Interface (continued) M25_TXCLK TIMIN M25_TXD [9:0] TIMAX Figure 29 - Gigabit TBI Interface Transmit Timing M25_RXCLK M25_COL T2 T2 M25_RXD[9:0] T3 T3 Figure 30 - Gigabit TBI Interface Receive Timing Symbol T1 Parameter Min (ns) Max (ns) Note 1 6 CL = 20pf Max (ns) Note M25_TXD[9:0] Output Delay Time Table 16 - Output Delay Timing Symbol Parameter Min (ns) T2 M25_RXD[9:0] Input Setup Time 3 T3 M25_RXD[9:0] Input Hold Time 3 Table 17 - Input Setup Timing 104 Zarlink Semiconductor Inc. MVTX2603 Data Sheet M26_TXCLK M26_TXD [15:0] M26_TX_EN] M26_TX_ER G12-max G12-min G13-max G13-min G14-max G14-min Figure 31 - AC Characteristics- GMII M26_RXCLK G1 G2 M26_RXD[15:0] G3 G4 M26_RX_DV G5 G6 M26_RX_ER G7 G8 M26_RX_CRS Figure 32 - AC Characteristics – Gigabit Media Independent Interface -125Mhz Symbol Parameter Min (ns) G1 M[26]_RXD[15:0] Input Setup Times 2 G2 M[26]_RXD[15:0] Input Hold Times 1 G3 M[26]_RX_DV Input Setup Times 2 G4 M[26]_RX_DV Input Hold Times 1 G5 M[26]_RX_ER Input Setup Times 2 G6 M[26]_RX_ER Input Hold Times 1 G7 M[26]_CRS Input Setup Times 2 Max (ns) Note Table 18 - AC Characteristics – Gigabit Media Independent Interface Zarlink Semiconductor Inc. 105 MVTX2603 Data Sheet -125Mhz Symbol Parameter Min (ns) Max (ns) Note G8 M[26]_CRS Input Hold Times 1 G12 M[26]_TXD[15:0] Output Delay Times 1 6 CL = 20pf G13 M[26]_TX_EN Output Delay Times 1 6.5 CL = 20pf G14 M[26]_TX_ER Output Delay Times 1 6 CL = 20pf Table 18 - AC Characteristics – Gigabit Media Independent Interface (continued) M26_TXCLK TIMIN M26_TXD [9:0] TIMAX Figure 33 - Gigabit TBI Interface Transmit Timing M26_RXCLK M26_COL T2 T2 M26_RXD[9:0] T3 T3 Figure 34 - Gigabit TBI Interface Timing Symbol T1 Parameter Min (ns) Max (ns) Note: 1 6 CL = 20pf Max (ns) Note M26_TXD[9:0] Output Delay Time Table 19 - Output Delay Timing Symbol Parameter Min (ns) T2 M26_RXD[9:0] Input Setup Time 3 T3 M26_RXD[9:0] Input Hold Time 3 Table 20 - Input Setup Timing 106 Zarlink Semiconductor Inc. MVTX2603 Data Sheet 14.7.2 LED Interface LED_CLK LE5-max LE5-min LED_SYN LE6-max LE6-min LED_BIT Figure 35 - AC Characteristics – LED Interface Variable FREQ. Symbol Parameter Note Min (ns) Max (ns) LE5 LED_SYN Output Valid Delay -1 7 CL = 30pf LE6 LED_BIT Output Valid Delay -1 7 CL = 30pf Table 21 - AC Characteristics – LED Interface 14.7.3 SCANLINK SCANCOL Output Delay Timing SCANCLK SCANLINK SCANCOL C5-max C5-min C7-max C7-min Figure 36 - SCANLINK SCANCOL Output Delay Timing SCANCLK C1 C2 SCANLINK C3 C4 SCANCOL Figure 37 - SCANLINK, SCANCOL Setup Timing Zarlink Semiconductor Inc. 107 MVTX2603 Data Sheet -25MHz Symbol Parameter Note: Min (ns) Max (ns) C1 SCANLINK input set-up time 20 C2 SCANLINK input hold time 2 C3 SCANCOL input setup time 20 C4 SCANCOL input hold time 1 C5 SCANLINK output valid delay 0 10 CL = 30pf C7 SCANCOL output valid delay 0 10 CL = 30pf Table 22 - SCANLINK, SCANCOL Timing 14.7.4 MDIO Input Setup and Hold Timing MDC D1 D2 MDIO Figure 38 - MDIO Input Setup and Hold Timing MDC D3-max D3-min MDIO Figure 39 - MDIO Output Delay Timing 1MHz Symbol Parameter Note Min (ns) D1 MDIO input setup time 10 D2 MDIO input hold time 2 D3 MDIO output delay time 1 Table 23 - MDIO Timing 108 Zarlink Semiconductor Inc. Max (ns) 20 CL = 50pf MVTX2603 Data Sheet 14.7.5 I2C Input Setup Timing SCL S2 S1 SDA Figure 40 - I2C Input Setup Timing SCL S3-max S3-min SDA Figure 41 - I2C Output Delay Timing 50KHz Symbol Parameter Note Min (ns) S1 SDA input setup time 20 S2 SDA input hold time 1 S3* SDA output delay time 4 usec Max (ns) 6 usec CL = 30pf * Open Drain Output. Low to High transistor is controlled by external pullup resistor. Table 24 - I2C Timing Zarlink Semiconductor Inc. 109 MVTX2603 14.7.6 Data Sheet Serial Interface Setup Timing STROBE D4 D5 D1 D1 D2 D0 D2 Figure 42 - Serial Interface Setup Timing STROBE D3-max D3-min AutoFd Figure 43 - Serial Interface Output Delay Timing Symbol Parameter Min (ns) D1 D0 setup time 20 D2 D0 hold time 3µs D3 AutoFd output delay time D4 Strobe low time 5µs D5 Strobe high time 5µs 1 Table 25 - Serial Interface Timing 110 Zarlink Semiconductor Inc. Max (ns) Note 50 CL = 100pf For more information about all Zarlink products visit our Web Site at www.zarlink.com Information relating to products and services furnished herein by Zarlink Semiconductor Inc. trading as Zarlink Semiconductor or its subsidiaries (collectively “Zarlink”) is believed to be reliable. However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual property rights owned by Zarlink or licensed from third parties by Zarlink, whatsoever. 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