MDS213
12-Port 10/100Mbps + 1Gbps
Ethernet Switch
Data Sheet
Features
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October 2003
12 10/100Mbps Autosensing, Fast Ethernet ports
with Reduced MII Interface
Single Gigabit Ethernet port
Ordering Information
MDS213CG
• Supports both GMII and integrated Physical Coding
Sublayer with Ten Bit Interface (TBI) logic to
interface directly with Gigabit transceivers
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0°C to 70°C
Two-chip solution for 24+2 configuration
- 32-bit wide bi-directional pipe at 100Mhz provides 6.4Gbps pipe to connect two MDS213 chips
- Protocol filtering
- Local port filtering
Supports up to 6.548 Mpps system throughput
using non-blocking architecture
High performance Layer 2 packet forwarding and
filtering at full wire speed.
Very low latency through single store and forward
at ingress port and cut-through switching at
destination ports
Port Trunking and Load Sharing for high
bandwidth links between switches
On-chip address lookup engine and memory for
up to 2K MAC addresses
Parallel Flash interface for fast self initialization
Supports packet filtering and port security
- System wide filtering
- Aging control for secure MAC addresses
- Provides 256-port and ID Tagged Virtual LANs
(VLANs) 802.1Q
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- Static MAC destination and source address
filtering
- VLAN for multicast/broadcast filtering
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ID Tagging Insertion/Extraction
Supports IP Multicasting through IGMP Snooping
XpressFlow Quality of Service (QoS), IEEE
802.1p, supports 4 Level transmission priorities,
weighted fair queuing based packet scheduling,
user mapping of priority levels and weights
Full duplex Ethernet IEEE 803.2x flow control
minimizes traffic congestion
Supports back-pressure flow control for half
duplex mode
Flooding and Broadcasting control
Link status and TX/RX activity through serial LED
interface
Up to 64K using management CPU memory
CPU
SRAM
456 Pin HSBGA
Flash
CPU BUS
SRAM
64 bit
SRAM
MDS213
MDS213
64 bit
XPipe 32 bit
4 x 10/100
4 x Fast
10/100
4 x 10/100
Ethernet 1G
Ethernet
Fast Fast
Ethernet
G Ethernet
1G
G Ethernet
4 x 10/100
4 x 10/100
4 x 10/100
FastFast
Ethernet
Ethernet
Fast
Ethernet
24 + 2 System Configuration
Figure 1 - 24 10/100Mbps + 2Gbps Port System Configuration
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Zarlink Semiconductor Inc.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright 2003, Zarlink Semiconductor Inc. All Rights Reserved.
MDS213
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•
Data Sheet
Up to 16K using external buffer memory
Standard software modules available:
• Browser, GUI, and text menu
• IEEE 802.1d Spanning Tree Algorithm
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SNMP management
Telnet for remote control console
Automatic Booting via TFTP Protocols.
Remote Monitoring (RMON) and storage for a management agent
• IGMP for IP multicast
• GVRP, GMRP
•
Packaged in 456-Pin Ball Grid Array
Description
The Zarlink MDS213 is a 12-port 10/100Mbps + 1Gbps high-performance, non-blocking Ethernet switch with onchip address memory and address lookup engine. A single chip provides 12 - 10/100Mbps ports and 1 - 1000Mbps
port. The MDS213 can be utilized in both managed and unmanaged switching applications.
The 3.2 Gbps XPipe allows a high-speed connection between two MDS213 chips, providing a optimal, low-cost,
workgroup switch with 24 10/100 Fast Ethernet ports and 2 Gigabit Ethernet ports.
In half-duplex mode, all ports support back pressure flow control to minimize the risk of losing data for long activity
bursts. In full-duplex mode, IEEE 802.3x frame based flow control is used. With full-duplex capabilities, each Fast
Ethernet ports supports 200Mbps aggregate bandwidth connections, while the Gigabit Ethernet port supports 2
Gbps to desktops, servers, or other high-performance switches. The Physical Coding Sublayer is integrated onchip with Ten Bit Interface (TBI) and this Physical Coding Sublayer can be bypassed when the GMII interface is
used.
The MDS213 supports port trunking/load sharing on the 10/100Mbps ports. Port trunking/load sharing can be used
to group ports between interlinked switches for increased system bandwidth. Ports within a trunk must reside within
a single MDS213, such that trunks may not be configured across two switches.
The on-chip address lookup engine supports up to 2K MAC addresses and up to 256 IEEE 802.1Q Virtual LANs
(VLAN). Each port may be programmed to recognize VLANs, and will transmit frames along with their VLAN Tags,
for interoperability, to systems that support VLAN Tagging.
Each port independently collects statistical information using SNMP and the Remote Monitoring Management
Information Base (RMON - MIB). Access to these statistical counter/registers are provided via the CPU interface.
SNMP Management frames may be received and/or transmitted via the CPU interface and thus creates a complete
network management solution.
The MDS213 utilizes cost effective, high performance, pipelined SBRAM to achieve full wire speed on all ports
simultaneously. Data is buffered into memory, using 0-128 byte bursts, from the ingress ports, and transferred to an
internal transmit FIFO, before being sent from the frame memory to the egress output ports. Extremely high
memory bandwidth is therefore achieved, which allows each of the ports to be active without creating a memory
bottleneck.
The MDS213 is fabricated with 2.5 V technology, where the inputs are 3.3V tolerant and the outputs are capable of
directly interfacing to Low-Voltage TTL levels. The Zarlink MDS213 is packaged in a 456-pin Ball Grid Array.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
32
CPU Interface
HISCTM
Registers
Switch
Control
Memory
2k
SRAM
Search Engine
32
SBRAM
Frame Engine
Frame
Buffer
Memory 64
Reduced
Xpipe
Engine
Frame
Memory
Interface
3.2Gbps
XPipeTM
32
GMAC
Twelve
10/100 MACs
RMII
GMII/PCS(TBI)
Interface
LED Xface
GMII or PCS
Figure 2 - System Block Diagram
Note:
All registers are 32-bit width.
The Control Bus is 32-bits wide and the Memory Bus is 64-bits wide.
The MDS212 contains 12 Fast Ethernet Ports.
The LED interface has 3 output signals (1 data and 2 control).
The XPipe is 32-bits wide.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Table of Contents
1.0 Ball Signal Descriptions and Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
1.1 Ball Signal Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
2.0 Ball-Signal Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
3.0 The Media Access Control (MAC) and GIGABIT (GMAC). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
3.1 MAC/GMAC Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
3.2 The Inter-frame Gap . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
3.3 Ethernet Frame Limits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
3.4 Collision Handling and Avoidance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
3.5 Auto-negotiation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
3.6 VLAN Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
3.7 MAC Control Frames. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
3.8 Flow Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
3.8.1 Collision-Based Flow Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
3.8.2 IEEE 802.3x Flow Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
3.9 Frame Bursting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
4.0 Frame Engine Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
4.1 Transmission scheduling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
4.2 Buffer Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
5.0 Frame Buffer Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
5.1 Frame Buffer Memory configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
5.2 Frame Buffer memory usage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
5.2.1 Memory Allocation of a Managed System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
5.2.2 Frame Data Buffers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
5.2.3 Transmission Queues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
5.2.4 Mailing List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
5.2.5 VLAN Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
5.2.6 VLAN MAC Association Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
5.2.7 Unmanaged System memory allocation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
5.3 The Frame Memory Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
5.3.1 Local memory interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
6.0 Search Engine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
6.1 Layer 2 Search Process . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
6.1.1 VLAN Unaware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
6.1.2 VLAN Aware. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
6.2 Address and VLAN learning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
6.3 Flooding and Packet Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
6.4 Packet Filtering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
6.5 Address Aging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
6.6 IP Multicast . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
7.0 The High Density Instruction Set Computer (HISC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.1 Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.2 HISC architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.3 HISC Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.3.1 Resource Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
7.3.2 Resource Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.3.3 Switching Database Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.3.4 Send and Receive Frames for Management CPU. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.3.5 Communication Between HISC and Switching Hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.3.6 Communication Between Search Engine and HISC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.3.7 Communication Between HISC and Frame Engine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
7.4 Communication Between Management CPU and HISC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Table of Contents
7.4.1 CPU-HISC Communication Using Queues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
7.4.2 Mailbox. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
7.4.3 CPU-HISC MAIL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
7.4.4 HISC-CPU Mail . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
8.0 The XPipe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
8.1 XPipe Connection. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
8.2 XPipe Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
9.0 Physical Layer (PHY) Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
9.1 Reduced MII (RMII) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
9.2 The Gigabit Media Independent Interface (GMII) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
9.2.1 The MII Management Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
9.2.2 MII Command and Status Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
9.3 The Physical Coding Sublayer with Ten Bit Interface (TBI): . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
10.0 The Control Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
10.1 External CPU Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
10.1.1 Power On/Reset Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.1.2 CPU Bus Clock Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.1.3 Address And Data Buses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.1.4 Bus Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.1.5 Input/Output Mapped Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
10.1.6 Interrupt Request . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
10.2 Control Bus Cycle Waveforms. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
10.3 The CPU Interface in Unmanaged Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
10.3.1 Arbiter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
10.4 CPU Interface in managed mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
10.4.1 CPU Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
11.0 The LED Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
11.1 LED interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
11.1.1 Function Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
11.1.2 Port Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
11.1.3 LED Interface Time Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
12.0 Data Forwarding Protocol and Data Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
12.1 Data Forwarding Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
12.1.1 Frame Reception . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
12.1.2 Unicast Frame Forwarding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
12.1.3 Multicast Frame Forwarding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
12.2 Flow for Data Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
12.2.1 Unicast Data Frame to Local Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
12.2.2 Unicast Data Frame to Remote Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
12.2.3 Multicast Data Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
12.3 Flow for CPU Control Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
12.3.1 CPU Transmitting Unicast CPU Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
12.3.2 CPU Transmitting Multicast CPU Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
12.3.3 CPU Receiving Unicast Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
12.3.4 CPU Receiving Multicast frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
13.0 Port Mirroring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
13.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
13.2 Physical Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
13.2.1 Setting Register For Port Mirroring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
13.2.1.1 APMR- Port Mirroring Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
14.0 Virtual Local Area Networks (VLAN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
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14.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
14.2 VLAN Implementation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
14.2.1 Static Definitions of VLAN Membership . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
14.2.2 Dynamic Learning of VLAN Membership . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
14.2.3 Dynamic Learning of Remote VLAN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
14.2.4 MDS213 Data Structures For VLAN Implementation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
14.2.4.1 VLAN ID Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
14.2.4.2 VLAN MAC Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
14.2.4.3 VLAN Port Mapping Table (VMAP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
14.2.4.4 Port VLAN ID (PVID) Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
15.0 IP Multicast . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
15.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
15.2 IGMP and IP Multicast Filtering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
15.3 Implementation in MDS213 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
15.3.1 MCT Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
15.3.1.1 MCT Structure For Unicast Frame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
15.3.2 MCT structure for IP Multicast Packet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
16.0 Quality of Service (QOS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
16.1 Weighted Round Robin Transmission Strategy. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
16.2 Buffer Management Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
17.0 Port Trunking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
17.1 Unicast Packet Forwarding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61
17.2 Multicast Packet Forwarding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
17.2.1 Select One Forwarding Port per Trunk Group . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
17.2.2 Blocking Multicast Packets Back to the Source Trunk . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
17.3 MAC Address Assignment. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
18.0 Register Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
18.1 Register MAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
18.2 Register definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
18.2.1 Device Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
18.2.1.1 GCR - Global Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
18.2.1.2 DCR0 - Device Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
18.2.1.3 DCR1 - Signature, Revision & ID Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
18.2.1.4 DCR2 - Device Configuration Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
18.2.1.5 DCR3 - Interfaces Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
18.2.1.6 MEMP - Memory Packed Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
18.2.2 Interrupt Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
18.2.3 Buffer Memory interface register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
18.2.3.1 MWARS - Memory Write Address Register - Single Cycle . . . . . . . . . . . . . . . . . . . . . . . . . 74
18.2.3.2 MRARS - Memory Read Address Register - Single Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . 74
18.2.3.3 Address Registers For Burst Cycle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
18.2.3.4 Memory Read/Write Data Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
18.2.3.5 VTBP - VLAN ID Table Base Pointer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
18.2.3.6 MBCR - Multicast Buffer Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77
18.2.3.7 AMA - RAM Counter Block Access Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77
18.2.3.8 Reserve Register 1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
18.2.3.9 Reserve Register 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
18.2.4 Frame Control Buffers Management Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
18.2.4.1 FCBSL - FCB Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
18.2.4.2 FCBST - FCB QUEUE - Buffer Low Threshold . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
18.2.4.3 BCT - (FCB) Buffer Counter Threshold . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
18.2.4.4 BCHL - Buffer Counter Hi-low Selection. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
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18.2.5 Queue Management Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
18.2.5.1 CINQ - CPU Input Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
18.2.5.2 COTQ - CPU Output Queue. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
18.2.6 Switching Control register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
18.2.6.1 HPCR - HISC Processor Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
18.2.6.2 HMCL0 - HISC Micro-code Loading Port - Low . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
18.2.6.3 HMCL1 - HISC Micro-code Loading Port - High. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
18.2.6.4 MS0R Micro Sequence 0 Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
18.2.6.5 MS0R Micro Sequence 1 Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
18.2.6.6 Flooding Control Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
18.2.6.7 MCAT - MCT Aging Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
18.2.6.8 Tpmxr – Trunk Port Mapping Table Index Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
18.2.6.9 TPMTD - Trunking Port Mapping Table Data Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
18.2.6.10 PTR - Pacing Time Regulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
18.2.6.11 MTCR - MCT Threshold & Counter Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
18.2.7 Link List Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
18.2.7.1 LKS - Link List Status Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
18.2.7.2 AMBX - Mail Box Access Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
18.2.7.3 AFML - Free Mail Box List Access Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
18.2.8 Access Control Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
18.2.8.1 AVTC - VLAN Type Code Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
18.2.8.2 AXSC - Transmission Scheduling Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
18.2.8.3 ATTL - Transmission Timing Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
18.2.9 MII Serial Management Channel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
18.2.9.1 AMIIC - MII Command Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
18.2.9.2 AMIIS - MII Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
18.2.10 Flow Control Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
18.2.10.1 AFCRIA - Flow Control RAM Input Address. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
18.2.10.2 AFCRID0 - Flow Control RAM Input Data 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
18.2.10.3 AFCRID1 - Flow Control RAM Input Data 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
18.2.10.4 AFCR - Flow Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
18.2.10.5 AMAR[1:0] - Multicast Address Reg. For MAC Control Frames. . . . . . . . . . . . . . . . . . . . . 89
18.2.10.6 AMCT - MAC Control Frame Type Code Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
18.2.10.7 ADAR [1:0] - Base MAC Address Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
18.2.10.8 ADAOR0 - MAC Offset Address Register 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
18.2.10.9 ADAOR1 - MAC Offset Address Register 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
18.2.10.10 ACKTM - Timer For SOF Checking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
18.2.10.11 AFCHT10 - Flow Control Hold Time Of 10Mbps Port . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
18.2.10.12 AFCHT 100 - Flow Control Hold Time Of 100Mbps Port . . . . . . . . . . . . . . . . . . . . . . . . . 91
18.2.10.13 AFCHT1000 - Flow Control Hold Time of Giga Port. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92
18.2.10.14 AFCOFT10 - Flow Control Off Time of 10Mbps PROT . . . . . . . . . . . . . . . . . . . . . . . . . . 92
18.2.10.15 AFCOFT100 - Flow Control Off Time of 100Mbps PORT . . . . . . . . . . . . . . . . . . . . . . . . 92
18.2.10.16 AFCOFT1000 - Flow Control Off Time of Giga Port. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
18.2.11 Access Control Function Group 2 (Chip Level) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
18.2.11.1 APMR- PORT MIRRORING REGISTER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
18.2.11.2 PFR - Protocol Filtering Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
18.2.11.3 THKM [0:7] - Trunking Forwarding Port Mask 0-7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
18.2.11.4 IPMCAS - IP Multicast MAC Address Signature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
18.2.11.5 IPMCMSK- IP Multicast MAC Address Mask . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
18.2.11.6 CFCBHDL - FCB Handle Register For CPU Read. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
18.2.11.7 CPU Access Internal RAMs (Tables) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
18.2.11.8 CPUIRCMD - CPU Internal RAM Command Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
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18.2.11.9 CPUIRDAT - CPU INTERNAL RAM DATA REGISTER. . . . . . . . . . . . . . . . . . . . . . . . . . . 98
18.2.11.10 CPUIRRDY - Internal Ram Read Ready For CPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
18.2.11.11 LEDR- LED Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
18.2.12 Ethernet MAC Port Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
18.2.12.1 ECR0 - ECR0 - MAC Port Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
18.2.12.2 ECR1 - MAC Port Configuration Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
18.2.12.3 ECR2 - MAC Port Interrupt Mask Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
18.2.12.4 ECR3 - MAC Port Interrupt Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
18.2.12.5 ECR4 - Port Status Counter Wrapped Signal. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
18.2.12.6 PVID Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
19.0 DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
19.1 Absolute Maximum Ratings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
19.2 DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
20.0 AC Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
20.1 XPIPE Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
20.2 CPU BUS Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111
20.3 Local SBRAM Memory Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
8
Zarlink Semiconductor Inc.
MDS213
Data Sheet
List of Figures
Figure 1 - 24 10/100Mbps + 2Gbps Port System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Figure 2 - System Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Figure 3 - Frame with Carrier Extension and Frame Bursting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
Figure 4 - Frame Buffer Memory Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Figure 5 - Memory Map of Managed System. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Figure 6 - Memory Map of an Unmanaged System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Figure 7 - Typical Packet Header Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Figure 8 - XPipe System Block Diagram for the MDS213 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Figure 9 - XPipe Message Header. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Figure 10 - Basic Timing Diagram of XPipe . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
Figure 11 - CPU Interface Configuration in Managed Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Figure 12 - Control Bus Configuration in Unmanaged Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
Figure 13 - Control Bus I/O . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Figure 14 - Block Diagram of the Arbiter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
Figure 15 - Little and Big Endian Byte Swapping Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
Figure 16 - An example of byte swapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
Figure 17 - LED Interface Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
Figure 18 - Time Diagram of LED Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
Figure 19 - Configuration of Mirror Port for MDS213 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
Figure 20 - Data Structure Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
Figure 21 - VLAN ID Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
Figure 22 - VLAN MAC Table. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
Figure 23 - Port Mapping Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
Figure 24 - Forwarding Port Mask Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
Figure 25 - Multicast Packet Forwarding Example. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
Figure 26 - XPIPE Interface - Output Valid Delay Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
Figure 27 - AC Characteristics - CPU BUS Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111
Figure 28 - Local Memory Interface - Input Setup and Output Valid Delay Timing . . . . . . . . . . . . . . . . . . . . . . . 113
Figure 29 - Port Mirroring Interface - Input Setup and Hold Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
Figure 30 - Port Mirroring Interface - Output Delay Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
Figure 31 - Reduce Media Independent Interface - Input Setup and Hold Timing. . . . . . . . . . . . . . . . . . . . . . . . 114
Figure 32 - Reduce Media Independent Interface - Output Delay Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
Figure 33 - Input Setup and Hold Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Figure 34 - Output Valid Delay Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Figure 35 - LED Interface - Output Delay Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
9
Zarlink Semiconductor Inc.
MDS213
Data Sheet
List of Tables
Table 1 - Type and Size of Memory Chips . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Table 2 - Frame Buffer Memory Usage for Managed Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Table 3 - Frame Buffer Memory Usage For Unmanaged Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Table 4 - Summary Description of the Source and Target End Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Table 5 - RMII Specification Signals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Table 6 - Bootstrapping Options. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
Table 7 - LED Signal Names and Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
Table 8 - MDS212 Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
Table 9 - Global Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
Table 10 - Device Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
Table 11 - AC Characteristics - XPipe Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110
Table 12 - AC Characteristics - CPU Bus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
Table 13 - AC Characteristics - Local SBRAM Memory Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
Table 14 - AC Characteristics - Port Mirroring Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
Table 15 - AC Characteristics - Reduced Media Independent Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
Table 16 - AC Characteristics - Gigabit Media Independent Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116
Table 17 - AC Characteristics - Physical Media Attachment Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
Table 18 - AC Characteristics - LED Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
10
Zarlink Semiconductor Inc.
MDS213
1.0
Data Sheet
Ball Signal Descriptions and Assignments
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
A AGND L_A2 L_A1 L_A1 L_A8 L_A4 X_D X_D X_D X_D X_D X_D X_D X_D X_DC X_DI X_DI X_DI X_DI X_DI X_DI X_DI X_DI P_CS P_RE P_GN
0
9
1
O29 O25 O20 O16 O13 O8 O5 O2 LKO 29
25
21
17
12
8
4
2
I#
Q1 TC
B Reser Rese L_A1 L_A1 L_A1 L_A5 X_D X_D X_D X_D X_D X_D X_D X_D X_FC X_DI X_DI X_DI X_DI X_DI X_DI X_DI X_DC Rese NC
ved rved 8
4
0
O30 O26 O21 O18 O14 O10 O4 O3
O
28
23
20
16
11
7
3
LKI rved
NC
C AVDD Rese Rese L_A1 L_A1 L_A6 X_D X_D X_D X_D X_D X_D X_D X_D X_DI X_DI X_DI X_DI X_DI X_DI X_DI X_DN Rese P_RE P_BR P_BL
rved rved 7
3
O31 O28 O24 O19 O15 O12 O6 O1 31
27
22
18
14
10
6
I
rved QC DY AST
D
L_D4 L_D1 L_CL NC L_A1 L_A1 L_A7 L_A3 X_D X_D X_D X_D X_D X_DE X_DI X_DI X_DI X_DI X_DI X_DI X_DI X_FC P_IN P_RD P_RS P_A8
K
6
2
O27 O23 O17 O11 O7 NO 30
24
19
15
9
5
1
I
T
Y#
T#
E
L_D6 L_D5 L_D2 L_D0 GND L_A1 VCC L_A9 VDD _X_D VCC X_D GND X_D X_DI VCC X_DI VDD X_DI VCC P_G GND P_AD P_A1 P_CL P_A7
5
O22
O9
O0 26
13
0
NT1
S#
0
K
F L_D11 L_D1 L_D8 L_D3 T_M
0
ODE
#
P_R P_A9 P_A4 P_A3 P_A2
WC#
G L_D1 L_D1 L_D1 L_D7 VCC
5
4
3
VCC P_A6 P_D3 P_D3 P_D2
1
0
9
H
L_D2 L_D1 L_D1 L_D1 L_D9
0
8
6
2
P_A5 P_A1 P_D2 P_D2 P_D2
8
6
4
J
L_D2 L_D2 L_D2 L_D1 VDD
4
3
1
7
VDD P_D2 P_D2 P_D2 P_D2
7
3
1
0
K
L_D2 L_D2 L_D2 L_D2 L_D1
9
7
6
2
9
P_D2 P_D2 P_D1 P_D1 P_D1
5
2
9
8
6
L
L_WE L_D3 L_D3 L_D2 VCC
O#
1
0
8
GND GND GND GND GND GND
VCC P_D1 P_D1 P_D1 P_D1
7
4
3
2
M L_BW L_OE L_W L_OE L_D2
0#
0# E1# 1#
5
GND GND GND GND GND GND
P_D1 P_D1 P_D1 P_D9 P_D8
5
0
1
N L_BW L_AD L_B L_B S_CL
3#
S# W2# W1# K
GND GND GND GND GND GND
VDD P_D7 P_D6 P_D4 P_D5
P L_BW L_B L_B L_B VDD
5
W4 W7 W6
GND GND GND GND GND GND
P_D0 T_D0 P_D1 P_D3 P_D2
R
L_D3 L_D3 L_D3 L_D3 L_D3
3
4
6
5
2
GND GND GND GND GND GND
T_D1 T_D4 T_D3 T_D2 T_D1
0
T
L_D3 L_D3 L_D3 L_D4 VCC
7
8
9
1
GND GND GND GND GND GND
VCC T_D9 T_D7 T_D6 T_D5
U
L_D4 L_D4 L_D4 L_D4 L_D4
0
2
3
6
7
T_D2 T_D1 T_D1 T_D1 T_D8
0
5
2
1
V
L_D4 L_D4 L_D4 L_D5 VDD
4
5
8
1
VDD T_D1 T_D1 T_D1 T_D1
9
6
4
3
W L_D4 L_D5 L_D5 L_D5 L_D5
9
0
2
6
7
PM_ T_D2 T_D2 T_D1 T_D1
DO[1] 5
1
8
7
Y
L_D5 L_D5 L_D5 L_D6
3
4
5
1 VCC
VCC PM_ T_D2 T_D2 T_D2
DEN 4
3
2
O
AA L_D5 L_D5 L_D6 M_CL M0_T
8
9
0
KI XD0
M12_ LE_# PM_ PM_ PM_
RXD5 SYN DI[1] DI[0] DENI
CI
AB L_D6 L_D6 M0_T M0_C
M2_L
M3_
M5_L
M6_T M8_T
M9_T
M10_
M11_
M12_
M_M LE_# LE_S PM_
2
3 XEN RS_D GND NK VCC CRS VDD NK VCC XD1 XD0 GND XD1 VCC RXD1 VDD TXD0 VCC TXER GND DC CLK YNC DO[0]
V
_DV
O
O
AC M0_L M0_T M0_R M1_T M2_T M2_ M3_T M4_L M4_ M5_T M6_T M7_L M7_CM8_R M9_T M10_ M10_ M11_ M12_ M12_ M12_ M12_ M12_ M_M LE_D LE_D
NK XD1 XD1 XEN XD1 RXD XD1 NK RXD XD0 XEN NK RS_D XD1 XEN TXEN RXD0RXD1 TXD0 TXD3 TXD6 RXE RXD4 DIO
I
O
1
1
V
R
AD NC M0_R M1_T M2_T M2_C M3_T M4_T M4_ M5_T M5_ M6_C M7_T M7_RM8_C M9_T M9_R M10_ M11- M11_ M12_ M12_ M12_ M12_ M12_ M12_ M12_
XD0 XD1 XEN RS_D XD0 XEN CRS XD1 RXD RS_D XEN XD1 RS_D XD0 XD0 TXD0 TXEN RXD0 LNK TXD2 TXD7 RXD RXD3RXCLRXD0
V
_DV
0
V
V
V
K
AE NC M1_L M1_R M2_T M3_L M3_ M4_T M4_ M5_ M6_L M6_R M7_T M8_L M8_T M9_L M9_R M10_ M11_ M11_ M12_ M12_ M12_ M12_ M12_ NC M12_
NK XD0 XD0 NK RXD XD1 RXD CRS NK XD1 XD1 NK XEN NK XD1 TXD1 LNK CRS_ TXCL TXD1 TXD5 TXEN RXD7
RXD1
1
0 _DV
DV
K
AF M1_T M1_CM1_R M2_R M3_T M3_ M4_T M5_T M5_ M6_T M6_R M7_T M7_R M8_T M8_RM9_C M10_ M10_ M11_ M12_ M12_ M12_ GREF M12_ NC M12_
RXD2
XD0 RS_ XD1 XD0 XEN RXD XD0 XEN RXD XD0 XD0 XD0 XD0 XD1 XD0 RS_ LNK CRS_ TXD1 CRS COL TXD4 _CLK RXD6
0
1
DV
DV
DV
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
VCC
= 3.3VDC for I/O (16 balls)
VDD
= 2.5VDC for core logic (10 balls)
GND
= Digital Ground for both VCC and VDD (42 balls)
AVDD
= 2.5VDC for Analog PLL (1 ball)
AGND
= Isolated Analog Ground for AVDD (1 ball)
NC
= No Connection
Reserved = Do Not Connect
11
Zarlink Semiconductor Inc.
17
18
19
20
21
22
23
24
25
26
MDS213
1.1
Ball Signal
Assignments
Signal Name
Signal Name
Ball
No.
NC
D4
RESERVED
C3
AGND
A1
RESERVED
B1
AVDD
C1
T_MODE#
F5
RESERVED
C2
L_CLK
D3
L_D0
E4
L_D1
D2
L_D2
E3
L_D3
F4
L_D4
D1
L_D5
E2
L_D6
E1
L_D7
G4
L_D8
F3
L_D9
H5
L_D10
F2
L_D11
F1
L_D12
H4
L_D13
G3
L_D14
G2
L_D15
G1
L_D16
H3
L_D17
J4
L_D18
H2
L_D19
K5
L_D20
H1
L_D21
J3
L_D22
K4
L_D23
J2
Data Sheet
Ball
No.
Signal Name
Ball
No.
L_D24
J1
L_D44
V1
L_D25
M5
L_D45
V2
L_D27
K2
L_D46
U4
L_D26
K3
L_D47
U5
L_D28
L4
L_D48
V3
L_D29
K1
L_D49
W1
L_D30
L3
L_D50
W2
L_D31
L2
L_D51
V4
L_WE0#
L1
L_D52
W3
L_OEW#
M2
L_D53
Y1
L_WE1#
M3
L_D54
Y2
L_OE1#
M4
L_D55
Y3
L_BW0#
M1
L_D56
W4
L_BW1#
N4
L_D57
W5
S_CLK
N5
L_D58
AA1
L_BW2#
N3
L_D59
AA2
L_BW3#
N1
L_D60
AA3
L_ADS#
N2
L_D61
Y4
L_BW4#
P2
L_D62
AB1
L_BW5#
P1
L_D63
AB2
L_BW6#
P4
M0_LNK
AC1
L_BW7#
P3
M_CLKI
AA4
L_D32
R5
M0_TXEN
AB3
L_D33
R1
M0_TXD1
AC2
L_D34
R2
M0_TXD0
AA5
L_D35
R4
M0_CRS_DV
AB4
L_D36
R3
M0_RXD1
AC3
L_D37
T1
M0_RXD0
AD2
L_D38
T2
NC
AD1
L_D39
T3
NC
AE1
L_D40
U1
M1_LNK
AE2
L_D41
T4
M1_TXEN
AC4
L_D42
U2
M1_TXD1
AD3
L_D43
U3
M1_TXD0
AF1
12
Zarlink Semiconductor Inc.
MDS213
Signal Name
Ball
No.
Signal Name
Data Sheet
Ball
No.
Signal Name
Ball
No.
M1_CRS_DV
AF2
M6_TXD0
AF10
M11_TXD1
AF19
M1_RXD1
AF3
M6_CRS_DV
AD11
M11_TXD0
AB19
M1_RXD0
AE3
M6_RXD1
AE11
M11_CRS_DV
AE19
M2_LNK
AB6
M6_RXD0
AF11
M11_RXD1
AC18
M2_TXEN
AD4
M7_LNK
AC12
M11_RXD0
AD19
M2_TXD1
AC5
M7_TXEN
AD12
M12_CRS
AF20
M2_TXD0
AE4
M7_TXD1
AE12
AE20
M2_CRS_DV
AD5
M7_TXD0
AF12
M12_TXCLK/GP_TXCL
K
M2_RXD1
AC6
M7_CRS_DV
AC13
M12_LNK/GP_LNK
AD20
M2_RXD0
AF4
M7_RXD1
AD13
M12_TXD0/GP_TXD9
AC19
M3_LNK
AE5
M7_RXD0
AF13
M12_COL/GP_RXCLK1
AF21
M3_TXEN
AF5
M8_LNK
AE13
M12_TXD1/GP_TXD8
AE21
M3_TXD1
AC7
M8_TXEN
AE14
M12_TXD2/GP_TXD7
AD21
M3_TXD0
AD6
M8_TXD1
AF14
M12_TXD3/GP_TXD6
AC20
M3_CRS_DV
AB8
M8_TXD0
AB13
M12_TXD4/GP_TXD5
AF22
M3_RXD1
AE6
M8_CRS_DV
AD14
M12_TXD5/GP_TXD4
AE22
M3_RXD0
AF6
M8_RXD1
AC14
GREF_CLK
AF23
M4_LNK
AC8
M8_RXD0
AF15
M12_TXD6/GP_TXD3
AC21
M4_TXEN
AD7
M9_LNK
AE15
M12_TXD7/GP_TXD2
AD22
M4_TXD0
AE7
M9_TXEN
AC15
M12_TX_EN/GP_TXD1
AE23
M4_TXD0
AF7
M9_TXD1
AB15
M12_TX_ER/GP_TXD0
AB21
M4_CRS_DV
AD8
M9_TXD0
AD15
M12_RX_ER/GP_RXD0
AC22
M4_RXD1
AC9
M9_CRS_DV
AF16
M12_RX_DV/GP_RXD1
AD23
M4_RXD0
AE8
M9_RXD1
AE16
M12_RXD7/GP_RXD2
AE24
M5_LNK
AB10
M9_RXD0
AD16
M12_RXD6/GP_RXD3
AF24
M5_TXEN
AF8
M10_LNK
AF17
NC
AF25
M5_TXD1
AD9
M10_TXEN
AC16
NC
AE25
M5_TXD0
AC10
M10_TXD1
AE17
M12_RXD5/GP_RXD4
AA22
M5_CRS_DV
AE9
M10_TXD0
AD17
M12_RXD4/GP_RXD5
AC23
M5_RXD1
AF9
M10_CRS_DV
AF18
M12_RXD3/GP_RXD6
AD24
M5_RXD0
AD10
M10_RXD1
AB17
M12_RXD2/GP_RXD7
AF26
M6_LNK
AE10
M10_RXD0
AC17
M12_RXD1/GP_RXD8
AE26
M6_TXEN
AC11
M11_LNK
AE18
M12_RXD0/GP_RXD9
AD26
M6_TXD1
AB12
M11_TXEN
AD18
M12_RXCLK/GP_
RSCLK0
AD25
13
Zarlink Semiconductor Inc.
MDS213
Signal Name
Ball
No.
Signal Name
Data Sheet
Ball
No.
Signal Name
Ball
No.
M_MDIO
AC24
T_D5
T26
P_D28
H24
M_MDC
AB23
T_D4/BS_RDYOP
R23
P_D29
G26
LE_DI
AC25
T_D3/BS_PSD
R24
P_D30
G25
LE_CLKO
AB24
T_D2/BS_SWM
R25
P_D31
G24
LE_SYNCI
AA23
T_D1/BS_RW
R26
P_A1
H23
LE_DO
AC26
T_D0/BS_BMOD
P23
P_A2
F26
LE_SYNCO
AB25
T_D0
P22
P_A3
F25
T_D31/PM_DO[1]
W22
P_D1
P24
P_A4
F24
T_D30/PM_DO[0]
AB26
P_D2
P26
P_A5
H22
T_D29/PM_DENO
Y23
P_D3
P25
P_A6
G23
T_D28/PM_DI[1]
AA24
P_D4
N25
P_A7
E26
T_D27/PM_DI[0]
AA25
P_D5
N26
P_CLK
E25
T_D26/PM_DENI
AA26
P_D6
N24
P_A8
D26
T_D25
W23
P_D7
N23
P_A9
F23
T_D24
Y24
P_D8
M26
P_A10
E24
T_D23
Y25
P_D9
M25
P_RST#
D25
T_D22
Y26
P_D10
M23
P_RWC#
F22
T_D21
W24
P_D11
M24
P_ADS#
E23
T_D20
U22
P_D12
L26
P_RDY#
D24
T_D19
V23
P_D13
L25
P_BRDY#
C25
T_D18
W25
P_D14
L24
P_BLAST#
C26
T_D17
W26
P_D15
M22
NC
B26
T_D16
V24
P_D16
K26
NC
B25
T_D15
U23
P_D17
L23
P_INT
D23
T_D14
V25
P_D18
K25
P_REQC
C24
T_D13
V26
P_D19
K24
P_GNTC
A26
T_D12
U24
P_D20
J26
P_REQ1
A25
T_D11
U25
P_D21
J25
P_GNT1
E21
T_D10
R22
P_D22
K23
P_CSI#
A24
T_D9
T23
P_D23
J24
RESERVED
B24
T_D9
T23
P_D24
H26
RESERVED
C23
T_D8
U26
P_D25
K22
X_FCI
D22
T_D7
T24
P_D26
H25
X_DCLKI
B23
T_D6
T25
P_D27
J23
X_DNI
C22
14
Zarlink Semiconductor Inc.
MDS213
Signal Name
Ball
No.
Signal Name
Data Sheet
Ball
No.
Signal Name
Ball
No.
X_DI0
E19
X_DENO
D14
L_A4
A6
X_DI1
D21
X_DO0
E14
L_A5
B6
X_DI2
A23
X_DO1
C14
L_A6
C6
X_DI3
B22
X_DO2
A14
L_A7
D7
X_DI4
A22
X_DO3
B14
L_A8
A5
X_DI5
D20
X_DO4
B13
L_A9
E8
X_DI6
C21
X_DO5
A13
L_A10
B5
X_DI7
B21
X_DO6
C13
L_A11
A4
X_DI8
A21
X_DO7
D13
L_A12
D6
X_DI9
D19
X_DO8
A12
L_A13
C5
X_DI10
C20
X_DO9
E12
L_A14
B4
X_DI11
B20
X_DO10
B12
L_A15
E6
X_DI12
A20
X_DO11
D12
L_A16
D5
X_DI13
E17
X_DO12
C12
L_A17
C4
X_DI14
C19
X_DO13
A11
L_A18
B3
X_DI15
D18
X_DO14
B11
L_A19
A3
X_DI16
B19
X_DO15
C11
L_A20
A2
X_DI17
A19
X_DO16
A10
RESERVED
B2
X_DI18
C18
X_DO17
D11
VCC
E7
X_DI19
D17
X_DO18
B10
VCC
E11
X_DI20
B18
X_DO19
C10
VCC
E16
X_DI21
A18
X_DO20
A9
VCC
E20
X_DI22
C17
X_DO21
B9
VCC
G5
X_DI23
B17
X_DO22
E10
VCC
G22
X_DI24
D16
X_DO23
D10
VCC
L5
X_DI25
A17
X_DO24
C9
VCC
L22
X_DI26
E15
X_DO25
A8
VCC
T5
X_DI27
C16
X_DO26
B8
VCC
T22
X_DI28
B16
X_DO27
D9
VCC
Y5
X_DI29
A16
X_DO28
C8
VCC
Y22
X_DI30
D15
X_DO29
A7
VCC
AB7
X_DI31
C15
X_DO30
B7
VCC
AB11
X_FCO
B15
X_DO31
C7
VCC
AB16
X_DCLKO
A15
L_A3
D8
VCC
AB20
15
Zarlink Semiconductor Inc.
MDS213
Signal Name
Ball
No.
Signal Name
Data Sheet
Ball
No.
VDD
E9
GND
P14
VDD
E18
GND
P15
VDD
J5
GND
P16
VDD
J22
GND
R11
VDD
N22
GND
R12
VDD
P5
GND
R13
VDD
V5
GND
R14
VDD
V22
GND
R15
VDD
AB9
GND
R16
VDD
AB18
GND
T11
GND
E5
GND
T12
GND
E13
GND
T13
GND
E22
GND
T14
GND
L11
GND
T15
GND
L12
GND
T16
GND
L13
GND
AB5
GND
L14
GND
AB14
GND
L15
GND
AB22
GND
L16
GND
M11
GND
M12
GND
M13
GND
M14
GND
M15
GND
M16
GND
N11
GND
N12
GND
N13
GND
N14
GND
N15
GND
N16
GND
P11
GND
P12
GND
P13
16
Zarlink Semiconductor Inc.
MDS213
2.0
Data Sheet
Ball-Signal Descriptions
The type of all pins is CMOS.
All input pins are 5 Volt tolerance.
All output pins are 3.3 CMOS drive.
CPU Bus Interface
Ball No(s)
Symbol
I/O
Description
G24, G25, G26, H24,
J23, H25, K22, H26.
J24, K23, J25, J26,
K24, K25, L23, K26,
M22, L24, L25, L26,
M24, M23, M25, M26,
N23, N24, N26, N25,
P25, P26, P24, P22
P_D[31:0]
I/O-TS, U
Processor Data Bus Data Bit [31:0]
E24, F23, D26, E26,
G23, H22, F24, F25,
F26, H23
P_A[10:1]
Input /Out - U
Processor Address Bus Address Bit [10: 1]
D25
P_RST#
In-ST
Processor Bus - Master Reset
F22
P_RWC#
Input/OutputTS, U
Processor Bus - Read/Write Control
Programmable polarity
E23
P_ADS#
Input/OutputTS, U
Processor Address Strobe
D24
P_RDY#
Out-OD- TS, U
Processor Bus - Data Ready
C25
P_BRDY#
Input- TS, U
Processor Bus - Burst Ready
C26
P_BLAST#
Input- TS, U
Processor Bus - Burst Last
D23
P_INT
Output
Processor Bus - Interrupt Request
Programmable polarity
E25
P_CLK
Input
Processor Bus - Bus Clock
A24
P_CSI#
Input- U
Chip Select
C24
P_REQC
Input
Bus Request from CPU - Only using in debug mode
when system is unmanaged.
A26
P_GNTC
Output
Bus Grant to CPU - Only using in debug mode
when system in unmanaged.
A25
P_REQ1
Input/Output
Bus Request from secondary MDS212 to primary
MDS212. Only using in debug mode when system
is unmanaged.
E21
P_GNT1
Input/Output
Bus Grant to secondary MDS212 from primary
MDS212. Only using in debug mode when system
is unmanaged.
Note:
17
Zarlink Semiconductor Inc.
MDS213
Data Sheet
# = 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
U = Internal weak pull-up
TS = Tri-state
ST = Schmitt Trigger
Frame Buffer Interface
Ball No(s)
Symbol
AB2, AB1, Y4,
AA3, AA2, AA1,
W5, W4, Y3, Y2,
Y1, W3, V4, W2,
W1, V3, U5, U4,
V2, V1, U3, U2, T4,
U1, T3, T2, T1, R4,
R3, R2, R1, R5,
L2, L3, K1, L4, K2,
K3, M5, J1, J2, K4,
J3, H1, K5, H2, J4,
H3, G1, G2, G3,
H4, F1, F2, H5, F3,
G4, E1, E2, D1,
F4, E3, D2, E4
L_D[63:0]
I/O-TS, U
Frame Buffer - Data Bit [63:0]
A2, A3, B3, C4,
D5, E6, B4, C5,
D6, A4, B5, E8, A5,
D7, C6, B6, A6, D8
L_A[20:3]
Output
Frame Buffer - Address Bit [20:3]
D3
L_CLK
Output
Frame Buffer Clock
N2
L_ADS#
Output
Frame Buffer Address Status Control
P3, P4, P1, P2, N1,
N3, N4, M1
L_BW[7:0]#
Output
Frame Buffer Individual Byte Write Enable
[7:0]
M3, L1
L_WE[1:0]#
Output
Frame Buffer Write Chip Select [1:0]
M4, M2
L_OE[1:0]#
Output
Frame Buffer Read Chip Select [1:0]
Ball No(s)
I/O
Description
RMII ETHERNET ACCESS PORTS [11:0]
AB23
M_MDC
Output
MII Management Data Clock - (Common for
all RMII Ports [11:0])
AB24
M_MDIO
I/O-TS
MII Management Data I/O - (Common for all
RMII Ports [11:0])
AA4
M_CLKI
Input
Reference Input Clock
18
Zarlink Semiconductor Inc.
MDS213
Data Sheet
Frame Buffer Interface (continued)
Ball No(s)
Symbol
I/O
Description
AC18, AB17,
AE16, AC14,
AD13, AE11, AF9,
AC9, AE6, AC6,
AF3, AC3
M[11:0]_RXD
[1]
Input-U
Ports [11:0] - Receive Data Bit [1]
AD19, AC17,
AD16, AF15,
AF13, AF11, AD10,
AE8, AF6, AF4,
AE3, AD2
M[11:0]_RXD
[0]
Input-U
Ports [11:0] - Receive Data Bit [0]
AE19, AF18, AF16,
AD14, AC13,
AD11, AE9, AD8,
AB8, AD5, AF2,
AB4
M[11:0]_CRS
_
DV
Input-U
Ports [11:0] - Carrier Sense and Receive
Data Valid
AD18, AC16,
AC15, AE14,
AD12, AC11, AF8,
AD7, AF5, AD4,
AC4, AB3
M[11:0]_TXE
N
Output
Ports [11:0] - Transmit Enable
AF19, AE17,
AB15, AF14,
AE12, AB12, AD9,
AE7, AC7, AC5,
AD3, AC2
M[11:0]_TXD[
1]
Output
Ports [11:0] - Transmit Data Bit [1]
AB19, AD17,
AD15, AB13,
AF12, AF10,
AC10, AF7, AD6,
AE4, AF1, AA5
M[11:0]_TXD[
0]
Output
Ports [11:0] - Transmit Data Bit [0]
AE18, AF17,
AE15, AE13,
AC12, AE10,
AB10, AC8, AE5,
AB6, AE2, AC1
M[11:0]_LNK
Input- ST, U
Ports [11:0] Link Status
GMII GIGABIT ETHERNET ACCESS PORT
Ball No(s)
Symbol
I/O
Description
AE24, AF24, AA22,
AC23, AD24,
AF26, AE26, AD26
M[12]_RXD[7:
0]
Input-U
Port [12] -- Receive Data Bit [7:0]
AD23
M[12]_RX_DV
Input-U
Port [12] -- Receive Data Valid
AC22
M[12]_RX_ER
Input- U
Port [12] -- Receive Error
19
Zarlink Semiconductor Inc.
MDS213
Data Sheet
GMII GIGABIT ETHERNET ACCESS PORT
Ball No(s)
Symbol
AF20
M[12]_CRS
Input- U
Port [12] - Carrier Sense
AF21
M[12]_COL
Input- U
Port [12] - Collision Detected
AD25
M[12]_RXCLK
Input- U
Port [12] - Receive Clock
AD22, AC21,
AE22, AF22,
AC20, AD21,
AE21, AC19
M[12]_TXD[7:
0]
Output
Port [12] -- Transmit Data Bit [7:0]
AE23
M[12]_TX_EN
Output
Port [12] -- Transmit Data Enable
AB21
M[12]_TX_ER
Output
Port [12] -- Transmit Error
AE20
M[12]_ TXCLK
Output
Port [12] - Gigabit Transmit Clock
AD20
M[12]_LNK
Input- ST, U
Port [12]--:Link Status
AF23
GREF_CLK
Input- U
Port [12] - Gigabit Reference Clock
Ball No(s)
I/O
Description
TBI GIGABIT ETHERNET ACCESS PORT [12]
AD26, AE26,
AF26, AD24,
AC23, AA22,AF24,
AE24, AD23, AC22
GP_RXD[9:0]
Input- U
Port [12] - TBI Receive Data Bit [9:0]
AF21
GP_RXCLK1
Input- U
Port [12] - TBI Receive Clock 1
AD25
GP_RXCLK0
Input- U
Port [12] - TBI Receive Clock 0
AC19, AE21,
AD21, AC20,.
AF22, AE22,
AC21, AD22,
AE23, AB21
GP_TXD[9:0]
Output
Port [12] - TBI Transmit Data Bit [9:0]
AE20
GP_TXCLK
Output
Port [12] - TBI Gigabit Transmit Clock
AD20
GP_LNK
Input- ST, U
Port [12] - TBI Link Status
AF23
GREF_CLK
Input - U
Port [12] - TBI Gigabit Reference Clock
XPIPE INTERFACE
Ball No(s)
Symbol
I/O
B23
X_DCLKI
Input
XPipe Data Clock Input
C22
X_DENI
Input
XPipe Data Enable Input
D22
X_FCI
Input
XPipe Flow Control Input
20
Zarlink Semiconductor Inc.
Description
MDS213
Data Sheet
XPIPE INTERFACE
Ball No(s)
Symbol
I/O
Description
C15, D15, A16,
B16, C16, E15,
A17, D16, B17,
C17, A18, B18,
D17, C18, A19,
B19, D18, C19,
E17, A20, B20,
C20, D19, A21,
B21, C21, D20,
A22, B22, A23,
D21, E19
X_DI[31:0]
Input
XPipe Data Input Bits [31:0]
A15
X_DCLKO
Output
XPipe Data Clock Output
B15
X_FCO
Output
XPipe Control Output
D14
X_DENO
Output
XPipe Data Enable Output
C7, B7, A7, C8,
D9, B8, A8, C9,
D10, E10, B9, A9,
C10, B10, D11,
A10, C11, B11,
A11, C12, D12,
B12, E12, A12,
D13, C13, A13,
B13, B14, A14,
C14, E14
X_DO[31:0]
Output
XPipe Data Output Bit [31:0]
PORT MIRRORING
AA26
PM_DENI
Input- TS, U
Port Mirroring Data Enable Input
AA25, AA24
PM_DI [1:0]
Input- TS, U
Port Mirroring Input Data Bit [1:0]
Y23
PM_DENO
Output
Port Mirroring Data Enable Output
AB26, W22
PM_DO[1:0]
Output
Port Mirroring Output Data Bit [1:0]
TEST FACILITY (sharing pins with other functions and for Testing purpose only)
F15
T_MODE#
I/O-TS, U
Test Pin - Set Mode upon Reset, and
provides test status output.
21
Zarlink Semiconductor Inc.
MDS213
Data Sheet
XPIPE INTERFACE
Ball No(s)
Symbol
I/O
Description
W22, AB26, Y23,
AA24, AA25,
AA26, W23, Y24,
Y25, Y26, W24,
U22, V23, W25,
W26, V24, U23,
V25, V26, U24,
U25, R22, T23,
U26, T24, T25,
T26, R23, R24,
R25, R26, P23
T_D[31:0]
Output
Test Output
AC25
LE_DI
Input- U
LED Serial Data Input Stream
AA23
LE_SYNC#
Input- U
LED Input Data Stream
AB24
LE_CLKO
Output
LED Serial Interface Output Clock
AC26
LE_DO
Output
LED Serial Data Output Stream
AB25
LE_SYNCO#
Output
LED Output Data Stream
LED INTERFACE
SYSTEM CLOCK, POWER AND GROUND PINS
Ball No(s)
Symbol
N5
S_CLK
E9, E18, J5, J22,
N22, P5, V5, V22,
AB9, AB18
E7, E11, E16, E20,
G22, L22, T22,
Y22, AB20, AB16,
AB11, AB7, Y5, T5,
L5, G5
I/O
Description
Input
System Clock at 100 MHz
VDD
Power
+2.5 Volt DC Supply
VCC
Power
+3.3 Volt DC Supply
22
Zarlink Semiconductor Inc.
MDS213
Data Sheet
SYSTEM CLOCK, POWER AND GROUND PINS
Ball No(s)
Symbol
I/O
Description
E5, E13, E22, L11,
L12, L13, L14, L15,
L16, M11, M12,
M13, M14, M15,
M16, N11, N12,
N13, N14, N15,
N16, P11, P12,
P13, P14, P15,
P16, R11, R12,
R13, R14, R15,
R16, T11, T12,
T13, T14, T15,
T16, AB5, AB14,
AB22
VSS
Power Ground
Ground
C1, C1
AVDD[1:0]
Analog Power
Used for the PLL
A1, A1
AVSS[1:0]
Analog Ground
Used for the PLL
P23
BS_BMOD
Input
CPU Bus mode
Must be set to 0
R26
BS_RW
Input
CPU Read/Write Control Polarity Selection
Default=1
0=R/W#;
1=W/R#
R25
BS_SWM
Input
Switch mode: Default=1
0=Managed mode
1= Unmanaged
R24
BS_PSD
Input
Primary Device Enable Pin Default=1
0=Secondary
1=Primary
R23
BS_RDYOP
Input
Option of merge the P_RDY# and
P_BRDY# as one pin Default=1
0=Merged pin
1=Separated pins
BOOTSTRAP PINS
Note:
# = 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
U = Internal weak pull-up
TS = Tri-state
ST = Schmitt Trigger
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Zarlink Semiconductor Inc.
MDS213
3.0
Data Sheet
The Media Access Control (MAC) and GIGABIT (GMAC)
The MDS213 MAC/GMAC contains twelve Fast Ethernet MACs and one Gigabit Ethernet MAC, defined by the
IEEE Standard 802.3 CSMA/CD. Each Fast Ethernet MAC is connected to a Physical Layer (PHY) via the Reduced
Media Independent Interface (RMII), and the Gigabit Ethernet MAC is connected to a PHY via the Gigabit Media
Independent Interface (GMII) or the Ten Bit Interface (TBI). The MAC/GMAC sublayer ("MAC/GMAC") consists of a
Transmit and Receive section and is responsible for data encapsulation/ decapsulation. Data encapsulation/
decapsulation involves framing (frame alignment and frame synchronization), handling source and destination
addresses, and detecting physical medium transmission errors. The MAC/GMAC also manages half-duplex
collisions, including collision avoidance and contention resolution (collision handling). The MDS213 includes an
optional MAC Control sublayer ("MAC Control") used for IEEE Flow Control functions.
During frame transmission, the MAC transmit section encapsulates the data by prepending a preamble and a Start
of Frame Delimiter (SFD), inserts a destination and source address, and appends the Frame Check Sequence
(FCS) for error detection. In VLAN aware switches, the MAC/GMAC inserts, replaces, or removes VLAN Tags from
these frame formats based on instructions from the Search Engine. When necessary, the MAC/GMAC regenerates
the Frame Check Sequence and performs "padding" for frames less than 64 bytes.
During frame reception, the MAC receive section verifies that the CRC is valid, de-serializes the data, and buffers
the frame into the Receive FIFO. The MAC/GMAC then signals the Frame Engine, using Receive Direct Memory
Access (RxDMA), that data is available in the FIFO and is ready for storage.
3.1
MAC/GMAC Configuration
MAC/GMAC operations are configured through the global Device Configuration Register (DCR2) and/or the
MAC/GMAC Control and Configuration Registers (ECR0, ECR1), defined in the Register Definition Section of the
MDS213 data sheet. The default settings for Autonegotiation, flow control, frame length, and duplex mode may be
changed and configured by the user on a per-port basis, either in hardware or software.
3.2
The Inter-frame Gap
The Inter-frame Gap (IFG), defined as 96 bit times, is the interval between successive Ethernet frames for the
MAC/GMAC. Depending on traffic conditions, the measurement reference for the IFG changes. If a frame is
successfully transmitted without a collision, the IFG measurement starts from the de-assertion of the Transmit
Enable (TXEN) signal. However, if a frame suffers a collision, the IFG measurement starts from the deassertion of
the Carrier Sense (CRS) signal.
3.3
Ethernet Frame Limits
A legal Ethernet frame size, defined by the IEEE specification, must be between 64 and 1518 bytes, referring to the
packet length on the wire. For transmitting or forwarding frames whose data lengths do not meet the minimum
requirements, the MAC/GMAC appends extra bytes (padding) from the PAD field. Frames, longer than the
maximum length may either be forwarded or discarded, depending on the register configuration. Although the
MAC/GMAC may be configured to forward oversized frames in the Device Configuration Register (DCR2), the
frame buffers' maximum size of 1536 bytes cannot be exceeded. For VLAN Aware systems, the maximum frame
size is increased from 1518 bytes to 1522 bytes to accommodate the 4-byte VLAN Tag.
3.4
Collision Handling and Avoidance
In half duplex mode, if multiple stations on the same network attempt to transmit at the same time, interference
could occur causing a collision. The MAC/GMAC monitors the Carrier Sense (CRS) signal to determine if the
medium is available before attempting to transmit data. If the transmission medium is busy, the MAC/GMAC defers
(delays) its own transmissions to decrease the load on the network. This is called collision avoidance.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
If a collision occurs, after the first 64 bytes of data, the MAC/GMAC ceases data transmission and sends the jam
sequence to notify all connected nodes of a collision. This jam sequence will persist for 32 bit times. The jam
sequence is a 32 bit predetermined pattern used to notify other nodes that there is a collision on the network.
If a collision occurs during preamble generation, or within the first 64 bytes, the transmitter waits until the preamble
is completed and then "backs off" (that is, stops transmitting) for a specific period (defined by the IEEE 802.3 Binary
Exponential Backoff Algorithm) before sending the jam sequence and rescheduling transmission. A frame with a
size no less than 96 bits (64 bits of preamble and 32 bits of jam pattern), is sent to guarantee that the duration of the
collision is long enough to be detected by the transmitting ports involved.
3.5
Auto-negotiation
The default value of the MDS213 MAC/GMAC enables Auto-negotiation. The default value is over written if the
PHY lacks the ability to support Auto-negotiation, which is ascertained through its respective management
interface, RMII/GMII. The Auto-negotiation process detects the different modes of operation (i.e. speed selection,
duplex mode) supported by the system at the other end of the link segment. Upon power on/reset, the PHY
generates a special sequence of fast link pulses (FLPs) to begin Auto-negotiation. The MDS213 MAC/GMAC,
supporting Auto-negotiation, reads the results from status register in the PHY (10/100 mode) or in the PCS
submodule (PCS Giga mode).
3.6
VLAN Support
Virtual Local Area Networks (VLANs) assemble a group of independent ports (and/or MAC addresses) to
communicate as if they were on the same physical LAN segment, without being restricted by the physically
connected hardware. The ports are logically grouped together by VLAN Identifiers (VLAN IDs). The MDS213
implements a MAC Address-based classification that associates each VLAN ID with its MAC address in the Switch
Database Memory (SDM) for purposes of aging out, or replacing, old VLANs.
The MDS213 MAC/GMAC recognizes VLAN-Tagged frame formats. During transmission, the MAC/GMAC inserts
(or extracts) the 4-byte VLAN Tag and regenerates the Frame Check Sequence for the transmitted frame. VLAN
support requires an increase in the maximum legal frame size, which is set in the Device Configuration Register
(DCR2), from 1518 to 1522 bytes. During transmission, if the MAC/GMAC is required to remove the VLAN Tag from
a 64-67 byte Rx frame, the MAC/GMAC will append extra bytes (pad) to form a 64 byte frame.
3.7
MAC Control Frames
MAC Control Frames, as defined by the IEEE, are used for specific control functions within the MAC Control
sublayer "MAC Control." Similar to data frames, control frames are also encapsulated by the CSMA/CD MAC,
meaning that they are prepended by a Preamble and Start of Frame delimiter and appended by a Frame Check
Sequence. These frames may be distinguished from other MAC frames by their length/type field identifier (88.08h).
The control functions are distinguished by an opcode contained in the first two bytes of the frame. Upon receipt,
MAC control parses the incoming frame and determines, by looking at the opcode and the MAC address, whether it
is destined for the MAC (a data frame) or for a specific function within MAC Control. After performing the specified
functions, the MDS213 discards all MAC control frames it receives, regardless of the port configuration. These
control frames are not forwarded to any other port and are not used to learn source addresses.
3.8
Flow Control
Flow control reduces the risk of data loss in the event a long burst of activity causes the MDS213 to saturate the
buffer memory with backlogged frames. The MDS213 supports two types of Flow Control: Collision-based for halfduplex mode and IEEE 802.3x Flow Control for full duplex mode. In both cases, the MDS213 recognizes
congestion by constantly monitoring available frame buffer memory. When the amount of free buffer space has
been depleted, the MDS213 initiates the flow control mechanism appropriate to the current mode of operation.
Setting the Flow Control (FC_Enable) bit in the MAC Port Configuration Register (ERC1) turns this operation on,
thereby initiating PAUSE frames or applying backpressure flow control when necessary
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Zarlink Semiconductor Inc.
MDS213
3.8.1
Data Sheet
Collision-Based Flow Control
Collision-based Flow Control, also referred to as Backpressure Flow Control, inhibits frame reception for ports
operating in half-duplex mode by "jamming" the link. When the free buffer space drops below a user-defined buffer
memory threshold, the MDS213 sends a jam sequence to all non transmitting ports, after approximately eight bytes
of payload data has been received, to generate a collision. The jam sequence is a predefined serial data stream
sent to all ports to indicate that there has been a collision on the network. These ports will delay (defer) the
transmission of data onto the network until the sequence has been completed.
3.8.2
IEEE 802.3x Flow Control
IEEE 802.3x Flow Control reduces network congestion on ports that are operating in full duplex mode using MAC
Control PAUSE frames and is managed by the Flow Control Management Registers. The full-duplex PAUSE
operation instructs the MAC to enable the reception of frames with a destination address equal to a globally
assigned 48-bit reserved multicast address of 01-80-C2-00-00-01. These PAUSE frames are subsets of MAC
Control frames with an opcode field of 0x0001 and are used by the MAC Control to request that the recipient stops
transmitting non-control frames for a specific period. The PAUSE Timer is loaded from the PAUSE frame and is
started upon the reception of a PAUSE frame. It will request a length of time for which it wishes to inhibit data frame
transmission.
In general, the IEEE standard allows pause frames longer than 64 bytes to be discarded or interpreted as valid. The
MDS213 recognizes all MAC Control frames (PAUSE frames) between 64 and 1518 bytes long. Any PAUSE
frames presented to the MAC outside of these parameters are discarded.
Preamble
SFD
DA
SA
DATA
PAD
FCS
Carrier Extension
Mll Frame Size: 512 bits
Slot Time: 4096 bits
FCS Coverage
Late Collision Threshold:
Slot Time - Header Size
= 4032 bits
GMAC Frame with Carrier Extension
Mac Frame with Extension InterFrame
Mac Frame
Inter Frame
Mac Frame
Burst Limit
65,536 bits
Carrier Event Duration
GMAC Frame Bursting
Figure 3 - Frame with Carrier Extension and Frame Bursting
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Zarlink Semiconductor Inc.
MDS213
3.9
Data Sheet
Frame Bursting
At speeds faster than 100Mbps and operating in half-duplex mode, the MAC/GMAC can transmit a series of frames
without relinquishing control of the transmission medium. This is called Frame Bursting. Frame Bursting is utilized
when a frame must be extended to the length of the slot time. With Frame bursting, only the first transmitted frame
requires extension. Once a frame has been successfully transmitted, the Transmit section may submit consecutive
frames onto the medium without contention, provided that no idle conditions exist between frames (e.g., no InterFrame Gap). The transmitting MAC/GMAC inserts extension bits, detected and extracted by the receiving
MAC/GMAC, into the Inter-frame space interval. The MAC/GMAC may continuously initiate burst frame
transmission up to the burst limit of 65,536 bits.
4.0
Frame Engine Description
The Frame Engine is the heart of the MDS213. It coordinates all data movements, ensuring fair allocation of the
memory bandwidth and the XPipe bandwidth.
When frame data is received from a MAC port, it is temporarily stored in the MAC Rx FIFO until the Frame Engine
moves it to the chip's external memory one granule (128-byte-or-less fragment of frame data) at a time. The Frame
Engine then issues the Search Engine a switching request that includes the source MAC address, the destination
MAC address, and the VLAN tag. After the Search Engine has resolved the address, it transfers the information
back to the Frame Engine via a switching response that includes the destination port and frame type (e.g. unicast or
multicast).
When the destination port is idle, the frame data is fetched from the memory and is written to the destination port's
MAC Tx FIFO. However, when the destination port is busy transmitting another frame, the Frame Engine writes a
transmission job that includes a frame handle for future identification. These transmission jobs are stored in the
destination port's transmission scheduling queues (TxQ). There are four TxQs per port, one for each priority class.
When the destination port is ready, the Frame Engine selects the head-of-line job from a TxQ. The frame, specified
by the job, will be fetched from the memory and will be written to the MAC TxFIFO.
For unicast frames, if the destination device is local (i.e., the destination port is located in the same device), the
Frame Engine writes a job into the destination port's transmission scheduling queue (TxQ). The Transmit DMA
(TxDMA) moves the frame data to the MAC Tx FIFO once the frame's transmission job is selected for transmission.
If the destination device is remote (i.e., the destination port is located on another device, and can only be reached
through the XPipe), all signaling between the two devices are sent as XPipe messages. The Frame Engine sends a
scheduling request message via the XPipe to the destination port. This message asks the remote Frame Engine to
write a job into the destination port's TxQ. When that job is selected, the remote Frame Engine sends a data
request message via the XPipe to the local Frame Engine. Reception of a data request message triggers the
forwarding engine module to forward the frame data to the destination port, one granule at a time through the XPipe
until the end of file (EOF) safely arrives at the remote port's MAC TxFIFO.
For multicast frames, the process is slightly different. The Frame Engine uses the VLAN index, which is part of the
search result, to identify the destination ports. For local destination ports, the Frame Engine writes a job to each
port's TxQ. When a transmission job is selected, the TxDMA moves data from the memory to the MAC Tx FIFO.
Multicast frame data is sent multiple times, until all local destination ports' requests are satisfied.
For a VLAN that includes remote destination ports, the multicast frame data is forwarded once through the XPipe
and then stored in the remote device's memory. The remote Frame Engine processes this multicast frame as if it
came from a local port.
A frame is stored in a Frame Data Buffer (FDB) until it is transmitted. FDBs are external, located in a MDS213's
frame buffer memory. To keep track of per-frame control information, the Frame Engine maintains one Frame
Control Buffer (FCB) per frame. FCBs are internal. Since the Frame Engine does not access the external memory
for frame control information, this conserves memory bandwidth for better performance.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
As a frame lives through its lifecycle, its status is updated in the FCB. The FCB also contains vital frame
information, such as destination port and length. There is a one-to-one correspondence between the FCB and the
FDB: FCB#274 contains information about the frame stored in FDB#274. An FCB/FDB pair is called a "frame
buffer," or simply a "buffer." The number 274 is called the handle or the buffer handle. The Frame Engine takes care
of the distribution and the releasing of buffers. It also keeps buffer counters to ensure no port or single type of traffic
occupies too many buffers.
The receiving DMA (RxDMA) moves frame data from the MAC RxFIFO to the FDB. Before the RxDMA writes frame
data into the FDB, it must obtain a free buffer handle from the buffer manager. A free buffer handle points to an
empty or released frame buffer, ensuring that no stored frame data will get overwritten. After the EOF has been
safely stored in the FDB, it writes the frame information to the FCB and issues a switching request to the Search
Engine. If the frame is found to be bad (e.g., bad CRC), the buffer handle will be released and nothing will be written
to the Search Engine or the FCB. This returns the buffer back to circulation and the frame is discarded.
The RxDMA can fail to obtain a free buffer handle for two reasons. All buffers are currently occupied, or the
received frame is a multicast frame and the multicast buffer quota is exhausted. In either case, the RxDMA will
discard the frame, without getting a handle. If set, the register bit DCR2[26], IPMC, enables IP multicast privileges.
If enabled, the RxDMA discards regular multicast frames if the multicast forwarding FIFOs occupancy exceeds the
programmable threshold (see register MBCR[21:20], MCTH). An IP multicast frame is discarded only when the
multicast frame's forwarding FIFO is full.
4.1
Transmission scheduling
There are four transmit scheduling queues (TxQ) per port, one for each priority. When a port is ready to transmit,
when the previous frame finished transmitting, the port control module notifies the Frame Engine. The Frame
Engine selects one TxQ out of the four priority queues, depending on the frame's arrival time and weighted round
robin state (refer to the QoS chapter for more detail). It reads an entry from the selected transmission scheduling
queue, and if the source port of the selected frame is local, a transmission request is issued to the local TxDMA
module. If, on the other hand, the source port is remote, the data request message is forwarded across the XPipe
and subsequently arrives at the forwarding engine.
The four transmit scheduling queues per output port allows the Frame Engine to perform weighted round robin
(WRR) to provide quality of service (QoS). The Search Engine classifies the frames into four internal priorities, Q0,
Q1, Q2, and Q3, in decreasing priority. The 802.1p priority bits are mapped to the internal priorities by a
programmable mapping, accessible via register AVTC. The user can program the queue weights via register AXSC,
and thereby control the relative rates of the four internal-priority tagged frames.
The maximum TxQ lengths are programmable from 128 entries to 1024 entries per queue. 52 TxQs are located in
the external memory. The maximum queue lengths and the base memory addresses are accessible by the register
group {CPUIRCMD, CPUIRDAT, CPUIRRDY}, under type QCNT.
4.2
Buffer Management
The buffer manager is responsible for the free handle allocation, buffer usage monitoring, buffer release and FCB
access control. Free handles point to buffers that are not occupied by a frame. These free buffers can be allocated
to a new frame received by the RxDMA. When the Frame Engine is done processing a frame, its handle is released
to the free handle pool.
The free handle pool must be initialized via the register group CPUIRCMD, CPUIRDAT, CPUIRRDY, type BMCT,
before device operation. The Buffer Manager Control Table (BMCT) is the pool of free handles. At reset, the BMCT
is empty. Prior to device operation, free handles must be written to the BMCT. The user must write the integers
{0,1,2,3, … K-1} to the BMCT one-at-a-time, where K is the maximum number of buffers. The value of K depends
on the external memory size and partition, and it can be 128, 256, 512, or 1024.
If all buffers are used, no more frames can enter the device. The Frame Engine keeps buffer counters that limit the
number of buffers occupied by frames destined for each output port. If a buffer counter exceeds a programmable
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
threshold, its associated output port is "blacklisted." Entering frames destined to this output port are discarded, until
the counter goes below the threshold. This threshold is programmed via registers BCT and BCHL. These counters
prevent complete depletion of buffers due to an overloaded port, thus allow frames destined for non-congested
ports to enter the system. This effectively avoids head-of-line blocking.
The Frame Engine also keeps a buffer counter for multicast traffic types. The buffers occupied by incoming
multicast frames are limited. This prevents multicast frames from blocking unicast ones from entering the system.
The threshold for multicast traffic types is programmed via register MBCR.
5.0
Frame Buffer Memory
5.1
Frame Buffer Memory configuration
The MDS213 system utilizes external SRAM for its Frame Buffer Memory configuration, where the size of memory
supported is ½ MB, 1MB and 2MB configurations. The following table shows four memory configuration examples
for the MDS213 system.
SRAM Type
One Bank
Two Bank
Address
Size
Address
Size
64Kx32
L_A[18:3]
½MB
L_A[19:3]
1M
128Kx32
L_A[19:3]
1MB
L_A[20:3]
2M
Table 1 - Type and Size of Memory Chips
The following figure shows the connections between the Frame Buffer Memory and the MDS213 for one-bank and
two-bank memory configurations.
CE
SRAM L_D[63:32]
64Kx32
CE
L_A[18:3]
L_A[19]
MDS213
L_D[63:32]
L_D[63:32]
Two Bank 1M
64Kx32
SRAM L_D[31:0]
128Kx32
L_D[31:0]
SRAM
SRAM64Kx32
128Kx32
CE
MDS213
SRAM L_D[63:32]
128Kx32
L_A[19:3]
L_A[19:3]
L_D[31:0]
SRAM
SRAM
64Kx32
64Kx32
One Bank 0.5M
64Kx32
L_A[19:3]
L_A[18:3]
MDS213
L_A[18:3]
L_A[18:3]
L_D[31:0]
SRAM
SRAM64Kx32
64Kx32
L_A[19:3]
L_A[18:3]
SRAM L_D[31:0]
64Kx32
CE
SRAM
SRAM
64Kx32
128Kx32
One Bank 1.5M
128Kx32
L_D[31:0]
L_A[19:3]
L_A[20]
L_D[63:32]
L_D[63:32]
Two Bank 1M
128Kx32
Figure 4 - Frame Buffer Memory Configuration
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Zarlink Semiconductor Inc.
MDS213
MDS213
5.2
Data Sheet
Frame Buffer memory usage
The MDS213 supports two switching modes: managed and unmanaged. The following tables describe Frame
Buffer Memory usage for managed and unmanaged modes of operation, respectively.
Description
Unit Size
Unit Count
Total Size
Reference by
Frame Data Buffer
(FDB)
1.5 Kbytes
256 to 1K
384 K bytes to 1.5M bytes
FE1
Transmission
Queue
4 bytes x 128K
to 4 bytes x 1K
52 (4 level
priority)
26 Kbytes to 208Kbytes
(at 4 level priority)
FE1
CPU/HISC Mailing
List
32 Bytes to 64
Bytes
(Programmable)
128 to 1K
4K bytes to
32 Kbytes
(at 32 Bytes each)
CPU, HISC & SE1
VLAN Table
8 bytes x 4K
1
32 Kbytes
HISC & SE1
VLAN MAC Table
8 bytes to 32
bytes x 2K
1
16 Kbytes to 64 Kbytes
HISC & SE1
Note: FE: Frame Engine, SE: Search Engine
Table 2 - Frame Buffer Memory Usage for Managed Mode
Description
Unit Size
Unit Count
Total Size
Reference by
Frame Data Buffer
(FDB)
1.5 Kbytes
256 to 1K
384 K bytes to 1.5M bytes
FE
Transmission
Queue
4 bytes x 128 to
4 bytes x 1K
52 (4 level
priority)
13 (1 level
priority)
26 Kbytes to 208 Kbytes
(at 4 level priority)
FE
HISC Mailing List
32 Bytes to 64
Bytes
(Programmable)
128 to 1K
4K bytes to
32 Kbytes
(at 32 Bytes each)
HISC & SE
Note: FE: Frame Engine, SE: Search Engine
In unmanaged mode, the system does not support VLAN features. Thus, VLAN related tables are not required.
Table 3 - Frame Buffer Memory Usage For Unmanaged Mode
5.2.1
Memory Allocation of a Managed System
In a managed system, the Frame Buffer Memory is partitioned into five segments: Frame Data Buffers (FDBs),
Transmission Queues, Mailing Lists, VLAN, and MCT VLAN Association Tables.
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MDS213
FDB block
must start from 0
63
Data Sheet
0
0
FDB
Frame Data Buffers
(1.5KB x # of frame buffers)
Transmission queues
(4x13 =52 queues)
(each entry = 1DW)
(#entry of Queue = 128 to 1K)
CPU/HISC Mailing List
(#entry = 128 to 1K)
(each mail entry=32 bytes
to 64 bytes)
VLAN Table
(4k entry, 8B/entry)
VLAN MAC Table
(2k entry)
(each entry=256, 128 or 64 bit)
Byte Byte Byte ByteByte ByteByte Byte
7
6
5
4
3
2
1
0
Programmable Size
Programmable Size
32KB
16, 32 or 64KB
MAX
1/2MB, 1MB or 2MB
Figure 5 - Memory Map of Managed System
5.2.2
Frame Data Buffers
The Frame Data Buffers (FDBs) accommodates the incoming data frames and partitions them into data blocks,
where each block occupies 1.5K bytes. The number of data blocks in FDB are configured by setting the value in the
register FCBSL[9:0]. Since MDS213 supports up to 2M Bytes memory, the maximum number of data blocks is 1K.
Note: The FDB must start at location 0.
5.2.3
Transmission Queues
The Transmission Queue controls the scheduling of the transmission ports, where each of these ports can support
up to 4 priorities for each of the 13 ports of the MDS213. The number of priorities is programmable. Thus, the
MDS213 may be configured for 13, 26, 39 or 52 Transmission Queues and may support 1, 2, 3 or 4 priority levels,
respectively. The size of the Transmission Queue is 128, 256, 512, or 1024 entries and may be setup during the
initialization phase.
The Search Engine maintains the contents of each queue, where each queue consists of transmission priorities.
Each double word (4-bytes) entry contains a FDB handle, which points to the corresponding frame in the buffer.
5.2.4
Mailing List
The Mailing List provides a communication channel between the HISC and CPU in managed mode. The size of a
mail entry varies, ranging from 32 to 64 bytes, which is determined by the initialization setup. When the CPU or the
HISC writes mail, the CPU/HISC can obtain a free mail by the register AFML that contains the addresses of free
mail. Conversely, when the CPU or HISC reads its mail, the CPU/HISC accesses the mail by the register AMBX
that contains the address of a CPU/HISC mail. All of the mail registers are maintained by the hardware.
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MDS213
5.2.5
Data Sheet
VLAN Table
The VLAN Table associates the ports to their respective VLANs, using the VLAN ID. The table contains 4K VLAN
entries, where each entry contains 8 bytes of information. The size of the VLAN Table is 32KB (4Kx8B). The base
address of the VLAN Table is specified by the VIDB in the VTBP bit [5:0].
Note: The VLAN Table must be located at the 32K boundary.
5.2.6
VLAN MAC Association Table
The VLAN MAC Table (VLAN MCT) associates each port's MAC address with its respective VLAN. The Table
comprises of 2048 entries, one entry per MAC address. Each VLAN MAC entry is mapped to each bit associated
with a VLAN specified by the VLAN Index. The size of the Table is defined by two bits in the VTBP register and
depends on the system configuration (e.g. the number of VLANs supported in the system). Each entry may consist
of 256, 128 or 64 bits (one bit per VLAN). The total size of the VLAN MAC Table may be 16, 32 or 64KB. The
VMACB field in the register VTBP specifies the base address.
Note: The VLAN MAC Table must be located at the 16K boundary.
5.2.7
Unmanaged System memory allocation
Since an unmanaged system does not support VLAN operation, the VLAN and VLAN MAC tables are not required.
Only the Frame Data Buffers, Transmission Queues, and HISC Mailing Lists are allocated in system memory.
0
63
FDB block
must start from 0
0
FDB
Frame Data Buffers
(1.5KB x # of frame buffers)
Transmission queues
(4x13 =52 queues)
(each entry = 1DW)
(#entry of Queue = 128 to 1K)
HISC Mailing List
(#entry = 128 to 1K)
(each mail entry=32 bytes
to 64 bytes)
Byte Byte Byte ByteByte ByteByte Byte
7
6
5
4
3
2
1
0
Programmable Size
Programmable Size
MAX
1/2MB, 1MB or 2MB
Figure 6 - Memory Map of an Unmanaged System
5.3
5.3.1
The Frame Memory Interface
Local memory interface
Each frame within the MDS213 is allocated its own buffer memory. The primary function of the Frame Buffer
Memory is to provide a temporary buffering space for both received and transmitted frames, as well as frames
waiting in the transmission queue. The actual usage depends on the frame type to be transmitted, either unicast or
multicast and the relationship between the source and destination ports. The buffer memory also, contains other
control structures including stacks, queues, other control tables. The buffer memory may be configured for 128K,
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MDS213
Data Sheet
256K, 512K, 1024K Bytes depending on the application of the system designer. The MDS213 local memory
interface supports up to 2M bytes of SRAM.
6.0
Search Engine
The Search Engine is responsible for determining the destination information for all packet traffic that enters the
MDS213. The results from all address or VLAN searches are passed to the Frame Engine to be forwarded, or on to
the HISC block for further processing. The result messages to either the Frame Engine or the HISC provide all the
needed information to allow the destination block to process the packet.
The Search Engine has been optimized for high throughput searching, utilizing the integrated Switch Database
Memory (SDM). The internal SDM contains up to 2k MAC Control Table (MCT) entries. These MCT entries are
searched utilizing one of four Hashing algorithms that can be selected. This provides the capability of changing the
search hashing to optimize the hash tables based on the traffic patterns in a given network. For example, if a
company gets all their Network Interface Cards (NIC) from one vendor, then the source and destination MAC
addresses will have common fields. This can lead to inefficient search hashing. With 4 different hash selections that
utilize different parts of the address fields, and can be 8, 9, or 10 bits in length, the hashing algorithm that works
best for a user's network can be selected (by testing each hash algorithm).
Layer 1
Layer 2
Preamble
ENET 2
Header
SFD
DATA
FCS
Packet
Destination MAC Address
Destination MAC Address
Source MAC Address
Source MAC Address
VLAN Tag
0x800
Ver
IHL
Typ of Serv
Time to Live
Layer 3
Total Length
Fig
Identifier
Protocol
IP Header
Fragment Offset
Header Checksum
IP Source Address
IP Destination Address
64 Bytes
Options + Padding
Destination Port #
Source Port #
Sequence Number
Layer 4
TCP/IP
Header
Acknowledgement Number
Offset Reserved U A P R S F
Checksum
Window
Urgent Pointer
Options + Padding
Data
.
.
.
Figure 7 - Typical Packet Header Information
The search process begins when the Frame Engine transfers the first 64 bytes of a packet header to the Search
Engine. These bytes are parsed to extract the information needed to perform the search for the MCT entries that
match the source and destination MAC address, generate the search hash keys, lookup VLAN membership, and
other packet status information.
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MDS213
6.1
Data Sheet
Layer 2 Search Process
When the MDS213 is in either a "forwarding" state (able to forward packets) or a "learning" state (able to learn new
addresses), the Search Engine is capable of performing address searches. The search process begins when
packet header information is transferred to the Search Engine from the Frame Engine.
The Search Engine first checks to determine if the MDS213 is configured to support Virtual Local Area Networks
(VLAN). If VLANs are enabled, the Search Engine will search for both the destination MAC address, to get
destination resolution information, and the source MAC address, to get the port's VLAN membership and verify the
validity of the port's VLAN membership. If VLANs are disabled, the Search Engine will search for the destination
and source MAC addresses but will not do a VLAN table check.
6.1.1
VLAN Unaware
When VLANs are not enabled or configured, the Search Engine will search the internal switch database memory for
an MCT that matches the destination MAC address. When a match is found, the Search Engine will check to
ensure that the destination address is not to be filtered before sending a search result message back to the Frame
Engine to start the packet forwarding process. At the same time, a search for the MCT that matches the source
MAC address is also performed. If no match is found for the source address, then the source MAC address needs
to be learned.
6.1.2
VLAN Aware
When VLANs are enabled and configured, the Search Engine will begin searching for the destination MCT and the
source MCT. If a matching MCT is found for the source address, then no learning is required, and the Search
Engine will check the VLAN membership of the source port. If the source port is a member of the VLAN, and the
destination port is also a member of the VLAN, then a normal response message will be passed to the Frame
Engine. If the source port is not a valid member of the VLAN, or the destination port is not a member of the VLAN,
then the Search Engine will decide to forward the packet or drop the packet depending upon a user defined
configuration. Then it will send a message to the HISC to allow the HISC to resolve the issue.
6.2
Address and VLAN learning
Address learning can be performed by either the HISC or the Search Engine and can be enabled or disabled. The
global learning control is set in the Device Configuration Register (DCR2). The Global Learning Disable (GLN) bit
controls whether learning is active or disabled, and can be set during initial power up configuration, or by an
external CPU before it begins modifying the SDM. It is necessary for an external CPU to disable learning before
updating or modifying MCT entries. This prevents the internal learning process from modifying MCT entries without
the CPU's knowledge.
When learning is globally enabled, by the Search Engine not finding a match to a source address search, it can
create a new MCT with the necessary information, and then notify the HISC that a new address has been learned.
If the Search Engine request queue becomes 3/4th full, the Search Engine will ignore address learning until the
request queue is less full. In that case, packets are forwarded as usual, and a message is sent to the HISC
requesting that the HISC learn the new address. If the Search Engine request queue is too full, and the HISC
request queue is full, then no learning will take place.
When two MDS213 chips are connected, and configured to operate with synchronized MCT entries, the HISC
processor has the ability to send a request to the Search Engine, instructing it to learn a new address received from
the other MDS213. The HISC processor can also use this method to make simple edits to the MCT entries for port
changes (i.e. source MAC address is now connected to a different port on the MDS213).
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MDS213
6.3
Data Sheet
Flooding and Packet Control
Packets, for which there are no matching destination MCT entries, are by default flooded to all output ports. This
can result in broadcast storms and cause the number of flooded packets to increase rapidly. The MDS213 provides
the user a means for setting a level of flooding, by providing a Flooding Control Register (FCR). The FCR allows the
user to define a time base (100us to 12.8ms) during which packet flooding at each output port will be counted.
Three separate flood control fields allow the user to specify flooding limits for:
•
Unicast to Multicast (flooded) packets per source port
•
Unicast to CPU packets per chip
•
Multicast to CPU packets per chip
During the time base period, three separate counters at each port count the number of packets meeting the flood
control types. Once a counter exceeds the allowed quantity, the Search Engine will then discard the packet and any
other packets of that type that enter the port during the remainder of the time base period. When the time base
period is completed, the three flood counters at each port are reset, and the counting process starts over.
The flooding control register is global for setting the limits on all register ports, but the individual ports have separate
counters to keep track of the number of flooded.
6.4
Packet Filtering
Packet filtering occurs during the address search phase. For static source or destination MAC address filtering,
there is a corresponding bit in the MCT entry that tells the Search Engine that the source or destination packet is to
be filtered.
When a match is found to a destination MAC address search, the "Destination Filter" (D) field in the MCT is
checked to determine if the destination address is to be filtered. If "D" is asserted, the Search Engine discards the
packet by sending a message to the Frame Engine telling it to release the Frame Control Buffer (FCB) where the
packet has been stored in the frame buffer memory. The packet thereby deleted from memory.
When a match is found to a source MAC address search, the "Source Filter" (S) field in the MCT is checked to
determine if the source address is to be filtered. If "S" is asserted, then the Search Engine discards the packet by
sending a message to the Frame Engine telling it to release the FCB for the packet.
6.5
Address Aging
Entries in the MCT database are removed if they have not been used within a user selectable time frame. This
aging process is handled by inspecting a single MCT entry during each clock period. If the entry is valid and subject
to aging, an aging flag in the MCT entry is cleared. If the aging flag is already set to zero during the inspection, an
aging message is sent to the HISC processor to delete and free up the aged MCT entry. Each time an MCT entry is
matched by way of a Search Engine, source search process, the aging flag is asserted to restart the aging process
for that entry.
Some entries may be static and not subject to aging. These MCT entries have a status field that identifies them as
being static, and will therefore always have their aging flag asserted. The network manager, using Zarlink
Management software, establishes static entries during a switch configuration session.
6.6
IP Multicast
The Search Engine supports the ability of the MDS213 to provide IP Multicast by identifying Internet Group
Multicast Protocol (IGMP) packets when parsing the packet header information provided by the Frame Engine.
IGMP packets are identified when the destination MAC address is 01-00-5E-xx-xx-xx, the Protocol field has the
value of 2, and the source IP address is 224.0.0.x.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
When an IGMP packet is identified, the Search Engine searches for the source address MCT entry, and then
passes a message to the HISC to allow it to setup or tear down the IP Multicast session. IP Multicast sessions are
treated as VLANs and use one of the 256 regular VLAN entries.
7.0
The High Density Instruction Set Computer (HISC)
7.1
Description
The High Density Instruction Set CPU (HISC) is specifically designed to implement highly efficient management
functions for the MDS213 switching hardware, minimizing the management activity intervention during frame
processing. The HISC services management requests based on an event-driven approach. Management requests
can be generated from either the management CPU or the switching hardware. The HISC is also designed with a
powerful instruction set and dedicated hardware interfaces for packet processing and transmission to provide high
performance packet transfers between the CPU interface and the switching hardware.
7.2
HISC architecture
The HISC is designed with an advanced pipeline architecture that combines the advantages of both RISC and
VLIW architectures. The HISC core combines a rich instruction set with 88 general-purpose registers and support
for multiple-way jump. The 88 registers are divided into three parts, eight common general-purpose registers and
two banks of 40 registers for two different task contexts. All registers are directly connected to the Arithmetic Logic
Unit (ALU), allowing two independent registers to be accessed in one single instruction execution. Each HISC
instruction may have up to three sub-instructions, which can be executed in one clock cycle. The resulting
architecture is more code efficient while achieving throughputs up to ten times faster than a CISC processor or up
to three times faster than a RISC processor. For a MDS213 running at 100MHz, the HISC can produce up to
300MIPs processing power.
7.3
HISC Operations
With an event-driven operation model, upon the request from either the Search Engine or external management
CPU, the HISC dynamically manages and maintains the Switch Database including MAC address entries, VLAN
and MAC-VLAN Association Tables. The HISC also provides an external management CPU a high-speed data
communication interfaces, so management packets can be transmitted to or received from the network.
In general, the service request is received from one of four different sources:
•
Messages from the management CPU
•
Requests from the switching hardware (Search Engine)
•
Real time clock
•
Interrupts to the management CPU
The HISC performs the following major operations:
•
Resource initialization
•
Resource management
•
Switching database management
•
Send and receive frames for management CPU
7.3.1
Resource Initialization
The HISC initializes all internal data structures including the mail box and switching database data structures, which
are used by the management CPU, HISC and switching hardware.
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Zarlink Semiconductor Inc.
MDS213
7.3.2
Data Sheet
Resource Management
The HISC can enforce a replacement policy when the number of free data structure for new MAC address entries is
lower than the predefined threshold.
7.3.3
Switching Database Management
One of the major management tasks required of the HISC is to create, delete, and modify MAC address entries
upon requests from the Search Engine or management CPU. Generally, the Search Engine performs the learning
of new MAC addresses identified in the packet streams. For a single MDS213 system, the HISC simply informs the
management CPU regarding the newly learned MAC addresses.
The HISC may also create, delete, or modify the MAC address entries based on the requests from the
management CPU. For a multi-MDS system, the HISC is response for synchronizing the switching databases. In
addition to the MAC address entries, the HISC also maintains the following database information required for
switching:
•
•
•
Create, delete and modify VLAN table in the switching database.
Create, delete and modify MAC VLAN table in the switching database.
Create, delete and modify IP Multicast entries in the switching database.
7.3.4
Send and Receive Frames for Management CPU
The HISC delivers BDPU, SNMP and other frames to and from the management CPU. In unmanaged mode, the
HISC also responds to interrupts destined to the management CPU.
7.3.5
Communication Between HISC and Switching Hardware
High-speed communication channels are required to provide fast message deliveries between the HISC and
switching hardware. Two high-performance FIFOs provide the required communication channels. They are
between the HISC and the Frame Engine, and between the HISC and Search Engine.
7.3.6
Communication Between Search Engine and HISC
The first high-speed FIFO is used by the Search Engine to send messages, management requests or received
packets, to the HISC. Whenever a message is sent to the FIFO, the HISC is notified of the new event. Each
message may contain up to two command codes, processed by the HISC sequentially. The HISC can also request
from the Search Engine to do operations such as search or learn via a HISC I/O interface. After processing the
requests, the Search Engine then sends the response back to the HISC via the FIFO.
7.3.7
Communication Between HISC and Frame Engine
The second high-speed FIFO is used by the HISC for sending data transfer requests to the Frame Engine.
Whenever a packet-forwarding request is received from the management CPU, the HISC forwards the request to
the Frame Engine via the FIFO. To alleviate the workload of the management CPU, certain management packets
can be processed by the HISC, and then forwarded to the Frame Engine for transmission via the FIFO.
7.4
Communication Between Management CPU and HISC
The HISC serves as an intermediary communication channel between the switching hardware and the external
management CPU. There are two communication mechanisms provided for messages exchanged between the
management CPU and HISC.
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MDS213
7.4.1
Data Sheet
CPU-HISC Communication Using Queues
The first communication mechanism is a pair of Input and Output Queues between HISC and management CPU.
The management CPU input/output queue is a very efficient mechanism for a single 32-bit data exchange between
the HISC and management CPU. In general, a management frame, i.e., Bridged Data Protocol Units (BDPU), is
forwarded directly from the HISC to the management CPU via the CPU Output Queue. Small management
requests, less than 24 bits, are delivered to the HISC via the CPU Input Queue.
7.4.2
Mailbox
The second communication mechanism is a hardware mailbox that can support variable size messages,
exchanged between the management CPU and the HISC. A major use of the mailbox is to exchange information
required for updating the switching database.
7.4.3
CPU-HISC MAIL
When the management CPU sends a mail message to the HISC, the CPU acquires an address of a free mail from
the free mail list (via register AFML). It then writes the mail content to the given memory address. Afterward, it
sends the mail to the HISC via the Mailbox Access (AMBX) Register. Whenever a management mail message is
received, an event is generated to inform the HISC to process the mail message.
7.4.4
HISC-CPU Mail
When a mail message arrives from the HISC, the mailbox hardware sends an interrupt, namely "Mail Arrive"
(MAIL_ARR) to the CPU. The CPU can then access the mail via the Mailbox Access Register (AMBX). At this point,
the CPU reads the mail handle and retrieves the contents of the mail from the AMBX Register.
8.0
The XPipe
The XPipe provides a high-speed link between systems utilizing two MDS213 devices. The XPipe incorporates a
32-bit-wide data pipe, with a high-speed point-to-point connections, and a full-duplex interface between devices.
While operating at a 100MHz, this interface can provide 3.2G bits per second (Gbps) of bandwidth per pipe in both
directions.
8.1
XPipe Connection
Transmit FIFO
Xmit
Ctrl
Source
Receive FIFO
Recd
Ctrl
Target
X_DI[31:0]
X_DCLKI
X_DENI
X_DO[31:0]
X_DCLKO
X_DENO
X_FCO
X_FCI
X_DO[31:0]
X_DCLKO
X_DENO
X_DI[31:0]
X_DCLKI
X_DENI
X_FCI
X_FCO
Receive FIFO
Rcvd
Ctrl
Target
Transmit FIFO
Xmit
Ctrl
Source
MDS213
MDS213
Figure 8 - XPipe System Block Diagram for the MDS213
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
The XPipe interface employs 32 data signals and three control signals for each direction. The pin connections
between two MDS213 devices are depicted in Figure 8. These 32 data signals form a 32-bit-wide transmission data
pipe that carries XpressFlow messages to and from the devices. The direction of all signals are from the source to
the target device, except for the flow control signal, which sends messages in the opposite direction; from the target
to the source. The three control signals consist of: a Transmit Clock signal, a Transmit Data Enable signal, and a
Flow Control signal.
The Transmit Clock signal (X_DCLKO), provides a synchronous clock to sample the data signals at the target
device. The source device provides the Transmit Data Enable signal (X_DENO) that envelops an entire XPipe
message (including the Header and the Payload) and is used to identify the message boundary from the received
data stream. The timing relationship between the data, clock, and data enable signals are described in the XPipe
Timing (Section 10.2).
The Flow Control signal (X_FC) monitors the state of the receiving queue at the target end to prevent XPipe
message loss. When the target end does not have enough space to accommodate an entire XPipe message, the
target device sends a XOFF signal by driving the X_FCO signal to LOW. The source device will stop further
transmission until the X_FCI signal asserts the XON state, which is an active HIGH (Refer to Table 4).
Signal Name
Description
Source End
Target End
X_DO[31:0]
X_DI[31:0]
32-bit-wide Transmit Data Bus - Includes a XPipe Message
Header and follows by the data payload
X_DCLKO
X_DCLKI
Transmit Clock - Synchronous data clock provided by the source
end
X_DENO
X_DENI
Transmit Data Enable - Provided by the source end to envelop
the entire XPipe message
X_FCI
X_FCO
Flow Control Signal- A flow control pin from the target end to
signal the source end to active XON/XOFF.
Table 4 - Summary Description of the Source and Target End Signals
The XPipe Message Header provides the payload size, type of message, routing information, and control
information for the XPipe incoming message. The routing information includes the device ID and port ID. The
header size is dependent upon the message types and may be 2 to 4 words in length.
0-64 Words Payload
2-4 Words Header
XpipeFlow Message
Header
Data Payload
Figure 9 - XPipe Message Header
8.2
XPipe Timing
The source device generates the X_CLKO signal to provide a synchronous transmit data clock. The Receiver will
then sample the data on the falling (negative) edge of the clock, as shown in Figure 10.
To identify the boundary between the XPipe messages and the data stream, the source device uses the X_DENO
signal to envelop the entire XPipe message. That is, a rising (positive) edge at the beginning of the first double word
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
(4 bytes) and a falling (negative) edge at the beginning of the last double word of an XPipe message as shown in
Figure 10.
Note: The negative edge does not occur at the end of the last double word, but instead, at the beginning of the last
double word. This allows XPipe messages to be sent consecutively (back-to-back).
.
Cycle #1 Cycle #2 Cycle #3 Cycle #4
Cycle #5
Cycle #6
.........
Last Cycle
Idle
X_CLKI/O
*1
X_DENI/O
X_DI/O[31:0]
D Word 0
D Word 1
D Word 2
D Word 3
.........
.........
.........
D Word N
Note 1: Positive edge at the beginning of the first Double Word.
Negative edge at the beginning of the last Double Word.
Figure 10 - Basic Timing Diagram of XPipe
9.0
Physical Layer (PHY) Interface
The Physical Layer Interface is designed to interface Zarlink chipsets to a variety of Physical Layer devices.
Reduced Media Independent Interface (RMII) is used for 10/100 interfaces, while Gigabit connections can use
either Gigabit Media Independent Interfaces (GMII) or Ten Bit Interface (TBI).
The chip ball names for the MAC use M as the first letter of the name, followed by their pin number, and then their
function. For example, M1_RXD0 refers to Mac port 1, receive data 0 of the receive data pair.
9.1
Reduced MII (RMII)
The MDS213 implements the Reduced Media Independent Interface (RMII) signals, REF_CLK, CRS_DV, RXD
[1:0], TX_EN, and TXD [1:0], defined in Section 5 of the RMII Consortium Specification. The purpose of this
interface is to provide a low cost alternative to the IEEE 802.3u [2] MII interface. Under IEEE 802.3u [2] an MII
comprised of 16 pins for data and control is defined. In devices incorporating many MACs or PHY interfaces such
as switches, the number of pins can add significant cost as the port counts increase. Zarlink MDS213 offer 12 or 24
ports, in one or two devices respectively. At 6 pins per port and 1 pin per switch ASIC, the RMII specification saves
119 pins plus the extra power and ground pins to support those additional pins for a 12 port switch ASIC.
Architecturally, the RMII specification provides for an additional reconciliation layer on either side of the MII but can
be implemented in the absence of an MII. The management interface (MDIO/MDC) is assumed to be identical to
that defined in IEEE 802.3u [2].
The RMII supports both 10 and 100Mbps data rates across a two bit Transmit Data (TXD) path and a two bit
Receive Data (RXD) path.
The RMII uses a single synchronous clock reference sourced from the Media Access Controller (MAC), or an
external clock source, to the Physical Layer (PHY). Doubling the clock frequency to 50 MHz allows a reduction of
required data and control signals, thereby providing a low cost alternative to the IEEE Std 802.3u Media
Independent Interface (MII). The RMII functions to make the differences between copper and optical PHYs
transparent to the MAC sublayer.
The RMII specification has the following characteristics:
•
•
It is capable of supporting 10Mbps and 100Mbps data rates
A single clock reference is sourced from the MAC to PHY (or from an external source)
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MDS213
•
•
Data Sheet
It provides independent 2 bit wide (di-bit) transmit and receive data paths
It uses TTL signal levels, compatible with common digital CMOS ASIC processes.
RMII Specification Signals
Signal Name
Direction
(with respect of the PHY)
Direction
(with respect to the MAC)
REF_CLK
Input or Output
Synchronous clock reference for
receive,
transmit and control interface
M[0:11]_CRS_DV
Input
Carrier Sense/Receive Data Valid
M[0:11]_RXD[1:0]
Input
Receive Data
M[0:11]_TX_EN
Output
Transmit Enable
M[0:11]_TXD[1:0]
Output
Transmit Data
M[0:11]_RX_ER
Input (Not required)
Receive Error
Table 5 - RMII Specification Signals
9.2
The Gigabit Media Independent Interface (GMII)
The GMII supports the 1000Mbps full-duplex operations of the MDS213, based on the Media Independent Interface
(MII) defined by IEEE Std 802.3 (Clause 22). The GMII retains the names and functions of most of the MII signals,
but defines valid signal combinations for 1000Mbps operations. The GMII transfers data in each direction for the
Data [7:0], Delimiter, Error, and Clock signals. The GMII implementation extends the Transmit Data (TXD) and
Receive Data (RXD) signals of the MII from four bits wide to eight bits wide and synchronizes the data and the
delimiters using a Gigabit Transmit Clock (GTX_CLK) instead of the MIIs' Transmit Clock (TX_CLK).
9.2.1
The MII Management Interface
The GMII uses the MII Management Interface is used to control and gather status information from the Gigabit
Physical Layer (PHY) to configure MDS213 operations using Auto-negotiation. The management interface consists
of a pair of signals, called the M_MDIO and M_MDC management pins.
9.2.2
MII Command and Status Registers
The MDS213 utilizes the MII Command and Status registers defined in the 10/100Mbps Specification and additional
extended registers to support Auto-negotiation (IEEE Std 802.3, Clause 37). The commonality of the MII
management registers will allow the MDS213 to determine the capabilities supported by the PHY and to implement
such functions as "Start of Frame" and "Determine PHY Address."
9.3
The Physical Coding Sublayer with Ten Bit Interface (TBI):
Zarlink MDS213 includes the Physical Coding Sublayer (PCS) block. It performs 8B/10B conversion between GMII
and Ten Bit Interface (TBI). The Collision Detect (COL) and Carry Sense (CRS) signals are generated from PCS to
GMII internally when using TBI interface PHY. The PCS block also includes an Auto Negotiation function. The PCS
block can be disabled by using the Device Configuration Register (DCR2) when GMII interface PHY is used.
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10.0
Data Sheet
The Control Bus
The CPU Interface, or Control Bus, provides the communication path between the system CPU and all other key
components within the MDS213 (i.e. the HISC). It operates in two modes: managed mode, where it utilizes an
external CPU, and unmanaged mode, where an external CPU does not exist.
In Managed mode, the CPU Interface provides the communication path between the systems' external CPU and
the HISC, Frame Buffer Memory (SRAM) or another MDS213. See Figure 11.
Control Bus
MDS213
MDS213
CPU
Flash
Memory
Figure 11 - CPU Interface Configuration in Managed Mode
In unmanaged mode, the CPU Interface provides the communication path between the Switch Devices and Flash
Memory, and between any two MDS213 Switches. See Figure 12.
Control Bus
Primary DEV
MDS213
Secondary DEV
MDS213
Flash
Memory
Arbitrator
Figure 12 - Control Bus Configuration in Unmanaged Mode
10.1
External CPU Support
The control bus comprises of a 32-bit wide CPU bus and supports Big and Little Endian CPU byte ordering. The
standard microprocessors supported include:
•
•
•
•
Intel 486 CPUs
Motorola MPC860 and 801 CPUs
Intel i960Jx CPU
MIPS processor with minimum conversion
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10.1.1
Data Sheet
Power On/Reset Configuration
On power-up, the following five Bootstrap bits, of Table 6, are used:
Name
Default
BS_BMOD
1
Functional Description
Bus Mode
Must be 0
BS_RW
1
Selects R/W Control polarity
0=R/W# 1=W/R#
BS_SWM
1
Switch Mode (only in Managed Mode)
0=Managed Mode 1=Unmanaged Mode
BS_PSD
1
Primary Device Enable (only in Unmanaged Mode)
0=Secondary Mode 1=Primary Mode
(The arbiter is activated in the chip with Primary Device.)
BS_RDYOP
1
Option of merger the P_RDY# and P_BRDY#
0=merged P_RDY# and P_BRDY# pin
1=Separated P_RDY# and P_BRDY# pins
Table 6 - Bootstrapping Options
10.1.2
CPU Bus Clock Interface
The CPU Interface allows the CPU bus clock to operate at clock rates different from the system clock rate. The
CPU Bus Clock rate is always less than or equal to the System Clock rate.
10.1.3
Address And Data Buses
The CPU Interface provides separate, non-multiplexed address and data buses. The data bus is a synchronous,
32-bit bus that can receive 16 or 32-bit wide data. The Flash memory uses a 16-bit data bus. The data bus supports
32 bit wide data for managed and unmanaged modes. The address bus supports 10 [10:1] address bits for
managed and unmanaged modes. Each device occupies 2048 bytes of Input/Output space.
10.1.4
Bus Master
The nomenclatures "Master" and "Slave" refer to the device that possesses the CPU Interface, or Control Bus,
while the designations of "Primary" and "Secondary" refer to the device that possesses the Bus Arbiter. The primary
or secondary device is determined during Power On/Reset, bootstrap options, while the master or slave device
changes dynamically, and will be determined by the Arbiter.
In managed mode, the systems' external CPU is the permanent master device. All other devices (e.g. the MDS213)
are designated as slave devices only. In unmanaged mode, the arbiter (located within the primary device) selects
one of the devices as the Master.
Note: In unmanaged mode, the primary device may be the Master or the Slave. The master device is the bus
master (controls the bus), while the other device is a slave device.
10.1.5
Input/Output Mapped Interface
The systems' external CPU accesses the switch devices' local memory using single-read/write or burst - read/write
I/O cycles. Burst I/O operations with auto address incrementing uses a 32-byte write data buffer and a 32-byte
cache read data buffer.
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10.1.6
Data Sheet
Interrupt Request
The CPU Interface accepts an Interrupt Request (IRQ) from each device connected to the interface, and supports
centralized interrupt arbitration and vector response. The interrupt output is an open-drain option with
programmable polarity.
10.2
Control Bus Cycle Waveforms
Sample
Burst
Read Cycle
Write Cycle
P_CLK
P_ADS#
P_RDY#
one-wait
state
P_A[10:1]
wait
wait Read
wait
Read Read Read Read
P_D[31;0]
P_BRDY#
P_BLAST#
Read Cycle = 8 clks
Figure 13 - Control Bus I/O
10.3
The CPU Interface in Unmanaged Mode
In unmanaged mode, the HISC processor of the Master device communicates with the slave device as a CPU
function. Three registers and one flag are used to communicate between the HISC processor and the CPU
Interface.
10.3.1
Arbiter
The arbiter of the XpressFlow MDS213 is an internal logic device used to determine which device will function as
the master device. The connections between the master device, slave device, and the CPU are used for debugging
purposes only. See Figure 14.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Only for Debug
CPU
P_REQC
P_GNTC
MDS213
Primary
MDS213
Secondary
Master
state
Machine
Bus
Request
Bus
Grant
P_REQ1
P_GNT1
P_CS
Arbiter
Master
state
Machine
Chip select
Figure 14 - Block Diagram of the Arbiter
Note: In unmanaged mode, the CPU is used only for debugging purposes and cannot be involved in switching
decisions or management activities.
During Power On/Reset, the bootstrap pin, BS_PSD, determines which device will be the primary and activates the
arbiter of that device. At most, three devices, two MDS213 devices and one CPU, can operate on the CPU
Interface at the same time.
Each device may request access to the CPU Interface by sending a Request signal to the arbiter. The arbiter, then
sends a Grant signal acknowledging which device has been chosen.
An arbitrate scheduler, located within the arbiter, decides which device functions as the Master device. If the Master
is the secondary device, the arbiter will send a Grant signal and a Chip Select (P_CS) signal to the device. If the
Master is the primary device, the Grant signal is sent directly to the Master State Machine (MSM) by an internal
signal. The scheduler then performs a round robin configuration and allows each device to be the Master device.
Note: During Power On/Reset, the arbiter always selects the primary device to be master device.
10.4
CPU Interface in managed mode
The CPU Slave State Machine (SSM) accepts Address Strobe (P_ADS#), Chip Select (P_CS#), and Bus-Data
Ready (P_RDY#) signals as ready state signals of a CPU cycle.
10.4.1
CPU Access
The 32-bit CPU bus interface supports both Big and Little Endian CPUs. The difference between Big and Little
Endian is the byte swapping when CPU writes data to external memory. Table 15 summarizes the byte swapping
operation and Figure 15 illustrates an example of bytes swapping.
If using Little Endian
Bit[1] must be ’0’ for register of
MWARS, MRARS, MWARB, MRARB
No byte swapping for CPU data write in or
read out to/from MWDR, MRDR registers.
If using Big Endian
Bit[1] must be ’1’ for register of
MWARS, MRARS, MWARB, MRARB
Automatic Byte swapping for CPU data write
in or read out to/from MWDR, MRDR
registers.
Figure 15 - Little and Big Endian Byte Swapping Operation
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Zarlink Semiconductor Inc.
MDS213
31
24 23
31
Internal Data Bus
16 15
Byte 1
Byte 0
CPU Bus
Data Sheet
24 23
Byte 3
8 7
Byte 2
16 15
8 7
Byte 1
Byte 2
0
Byte 3
0
Byte 0
Figure 16 - An example of byte swapping
11.0
The LED Interface
11.1
LED interface
The MDS213 LED interface supports the status per port in a serial stream that may be daisy-chained to connect
two MDS213 chips. Daisy-chaining greatly reduces the pin count and number of board traces routed from the
Physical Layer to the LEDs, thus simplifying system design and reducing overall system cost. For a large port
configuration such as the 24+2 in the MDS213, a large number of LED signals is needed, which may induce noise
and layout issues in the system. The LED information is transmitted in a frame-structured format with a
synchronization pulse at the start of each frame.
MDS213
Master
MDS213
Slave
LE_CLKO
LE_SYNCO
LE_SYNCO
LE_DO
LE_DO
LE_SYNCI
LE_DI
LEDDECODER
LED-DISPLAY
Figure 17 - LED Interface Connections
To provide the port status information from our MDS213 chips via a serial output channel, five additional pins are
required.
•
•
•
LE_CLKO - at 12.5 MHz
LE_SYNCI/O - a sync pulse -- defines the boundary between frames
LE_DI/O - a continuous serial stream of data for all status LEDs which repeats once every frame time
A low cost external device (i.e. a 44-pin FPGA-like device) decodes the LED framed data and drives the LED array
for display. This device may be customized for different system configurations.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
The port status of the MDS213 is transmitted to an external decoder via a serial output channel. In the MDS213, we
support cascading of this serial output channel between two devices. One MDS213 is configured as the master, this
initiates the start of LED information frames, and serializes information bits. The MDS213 slave repeats the
information sent from the master and appends its own information bits. To cascade these two devices, we will need
to extend the number of LED pins from 3 to 5. Figure 17 shows two cascaded LED interfaces and the connections
between the MDS213s, the LED decoder, and the LED display.
11.1.1
Function Description
The LED interface employs the following signals:
Signal Name
Master Device
Description
Slave Device
LE_CLKO
LED Clock-Synchronous LED clock provided by the slave device to LED
decoder at the system clock divided by 8 (~12.5Mhz).
LE_SYNCI
LE_SYNCO
LE_DI
LE_DO
A synchronous pulse -- defines the boundary between frames. The length
of each LED data frame is about 256 bits that shift out by LE_CLKO per bit.
A continuous serial stream of data for all status LEDs which repeat once
every frame time.
Table 7 - LED Signal Names and Descriptions
11.1.2
Port Status
In the MDS213, each port consists of 8 different LED status, represented by separate bits:
1. Flow Control
2. Transmitting Data
3. Receiving Data
4. Action (TxD or RxD)
5. Link UP/DOWN
6. Speed
7. Full Duplex/Half Duplex
8. Collision
In addition to the 13 ports of the MDS213, three extra user-defined status sets may be sent through the LED serial
channel for debugging or other applications, where each user-defined status set is also represented by 8 bits.
11.1.3
LED Interface Time Diagram
The Master needs to shift out (13+3)*8 status bits periodically. Thus, slave needs to shift out (13+3)*8 + (13+3)*8
status bits, which includes the status of the master device and itself.
The status of each port will be sampled by the LED State Machine every 20.5 µs, the time period of the frame. That
is, each LED data frame length equals (256)X 80nsec. Each frame is divided into two subframes: a master and a
slave sub-frame. Furthermore, each sub-frame is partitioned into 16 slots (13 MAC ports plus 3 user-defined sets)
and each slot will carry 8 status bits. The following figure shows the signal from the slave chip to LED decoder.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
One Frame
256x80nsec
Master dev sub-frame
16 slots
Cycle #0
Cycle #1 Cycle #2
Cycle #3 Cycle #4
Slave dev sub-frame
16 slots
Cycle #5 Cycle #6 Cycle #7 Cycle #8
LED_CLKO
LED_SYNCI/O
LED_DI/O
P0
bit 0
bit 1
bit 2
bit 3
bit 4
bit 5
bit 6
bit 7
P1
bit 0
bit 1
1* one pulse for every 256 cycles
Figure 18 - Time Diagram of LED Interface
12.0
Data Forwarding Protocol and Data Flow
12.1
Data Forwarding Protocol
12.1.1
Frame Reception
For normal frame reception, a 128-byte block of frame data is stored in the RxFIFO. This block may be shorter if an
End of Frame (EOF) arrives. At that point, the RxDMA will request the use of the internal memory bus. When this
memory request is granted, the RxDMA will move the block from the RxFIFO to the Frame Data Buffer (FDB).
The MAC ports are partitioned into two groups, one for the Gbps Port and one for all 12 of the 100Mbps Ports. The
service discipline is round robin for both the Gbps Port and 100/10Mbps group. After the entire frame is moved to
the frame data buffer (FDB), a switch request will be sent to the Search Engine (Reference Search Engine Section)
12.1.2
Unicast Frame Forwarding
For forwarding of the unicast frame, the Search Engine first resolves the destination device and the destination
port, and sends a switch response is sent back to the Frame Engine. The Frame Engine will obtain the type (unicast
or multicast), the destination port, and the destination device from the search response. After processing the search
response, the Frame Engine will notify the destination port that it has a frame to forward to the destination port's
TxFIFO.
For local forwarding (e.g. the destination port is in the local device), the Frame Engine will send the job to the
Transmission Scheduling queue of the destination port.
For remote forwarding (i.e. the destination port is in the remote device), the Frame Engine will create a data
forwarding request command message (DATA_FWD_REQ), which is sent via the XPipe to the remote device. The
remote Frame Engine, after receiving this DATA_FWD_REQ message, will place a job in the Transmission
Scheduling queue of the destination port.The port will serve the next job from the Transmission Scheduling queue
when the following two conditions are met:
•
•
It is enough room for a 1.5Kbyte frame (a maximum-sized frame) within the TxFIFO.
The end-of-frame (EOF) of the current frame has arrived at the TxFIFO.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
There are four transmission-scheduling queues for each port, one for each of the four classes of priority. The port
will send the jobs to the transmission scheduling queues according to a first in first out (FIFO) order.
To start data transmission, the port obtains a job from the transmission scheduling queue and notifies the Transmit
DMA (TxDMA) to move the data from the FDB to the MAC Transmit FIFO (TxFIFO) in 128-byte granules (for local
forwarding). Otherwise, the device sends a DATA_REQ command message via the XPipe to the source device to
request remote forwarding. The data forwarding engine module in the Frame Engine of the source device will then
forward the frame in 128-byte granules via the XPipe.
12.1.3
Multicast Frame Forwarding
After the reception of the switching response, a job is sent to the Transmission Scheduling queues of the
destination ports for local switching. However, for remote switching, one copy of the frame will be forwarded to the
remote device in 128-byte granules via the XPipe. This copy of the frame will be sent to the frame data buffer. The
Frame Engine, after the successful reception of this frame, will put jobs in the Transmission Scheduling queues of
the destination ports of its device.
When the TxFIFO is ready to receive the frame (same as the conditions stated in unicast frame forwarding section),
the TxDMA will forward the frame from the FDB to the destination ports in granule form. The maximum size of a
granule is 128 bytes.
12.2
Flow for Data Frame
The following subsections describe the flow of information during transfers of data frames, both unicast and
multicast.
12.2.1
Unicast Data Frame to Local Device
In the simplest case, the data frame is destined for a port on the local device. The Frame Engine moves the
received frame to the local FDB. The Search Engine forms a switch request with the frame header (includes source
MAC and Destination MAC) and passes it to the Switch Engine to resolve the destination. The Switch Engine then
provides a destination port address to the Frame Engine via a switch response message. Frame Engine transmits
put a transmission job in transmission scheduling. After the port is ready to send the frame, then frame start to
move the frame to TxFIFO. If the MAC address cannot be resolved by the Switch Engine, the HISC and/or the CPU
are queried to resolve the address. For unknown destination MAC, the frame will flood the frame into the source
VLAN domain.
12.2.2
Unicast Data Frame to Remote Device
In the case, the data frame is destined for a port on a remote device. First, the Frame Engine moves the received
frame to the local FDB. A switch request with frame header (includes source MAC and Destination MAC) is passed
to Switch Engine to resolve the destination. The Switch Engine then provides a destination port address to the
Frame Engine. If the address resolution cannot be completed by the Switch Engine, the HISC and/or the CPU are
queried.
Once the address is resolved, the two Frame Engines performs the following interactive handshaking procedures
via the XPipe:
•
•
•
Source Frame Engine sends a Data Forwarding Request message to Destination, where the destination
Frame Engine puts a job in the associated transmission scheduling queue.
When the destination port is ready to send the frame, the destination Frame Engine send a Data Request
message to the source Frame Engine.
After the source Frame Engine receives the Data Request Message, it start to move the frame in granule
form, which is directly written in the destination TxFIFO.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Note that, at the remote device, the frame is written into the transmit FIFO of the remote destination port. The frame
is not stored in the FDB of the remote device again, so that the latency can be reduce.
12.2.3
Multicast Data Frame
In this scenario, we assume that the multicast frame involve both local and remote ports. The received multicast
frame is written to the local FDB by the Frame Engine. After resolving the destinations, the Switch Engine then
provides local destination port addresses and remote port address to the Frame Engine. If the address resolution
cannot be completed by the Switch Engine, the HISC and/or the CPU are queried.
Frame Engine pushes the jobs to the corresponding transmission queues (per job per local port). When a local port
is ready for this multicast frame, the Frame Engine moves the frame to the corresponding TxFIFO. There is a
counter to track of the number of copies to be sent. The number is provided by Search Engine and the Frame
Engine keeps track of this counter. When a frame is sent, the counter is decreased by one. The FDB will be
released when the counter becomes zero.
When the destination ports involve remote ports, the frame is transferred over the XPipe to the remote Frame
Engine, which writes a single copy of it into the remote FDB. That is we use double store-and-forward for remote
multicast. After receiving the whole frame, the remote Frame Engine utilizes the control information in the internal
header, which indicates the associated destination ports in the remote device to push the jobs into the
corresponding transmission queues. When a port is ready for this multicast frame, the Frame Engine moves the
frame to the corresponding TxFIFO. Similarly, the Frame Engine also keeps track of the number of copy of frame to
be sent and release the frame when the counter is reduced to be zero.
12.3
Flow for CPU Control Frame
In managed system, CPU may transmit or receive CPU control frames, e.g., Protocols, SNMP frames to/from a
MAC port via a CPU unicast frame. On the other hand, a CPU may receive a multicast frame from a MAC port.
Moreover, CPU can transmit a multicast frame to multiple ports. Use four scenarios to illustrate the forwarding flow.
12.3.1
CPU Transmitting Unicast CPU Frame
The CPU initiates Unicast control messages, by first writing the frame into the FDB, and then sending a message to
the HISC. The HISC forwards a switch response to the Frame Engine, which transmits the frame to the destination
MAC port. After receiving switch response, Frame Engine performs the same unicast forwarding as for unicast data
frame. Refer previous subsection for unicast data frame mechanism.
12.3.2
CPU Transmitting Multicast CPU Frame
When the CPU sends a multicast control message to ports, the CPU first writes the frame to the local FDB. The
CPU then sends a message to the HISC, which provides a switch response message to the local Frame Engine.
After receiving switch response, Frame Engine performs the same multicast forwarding as for multicast data frame.
Refer previous subsection for multicast data frame mechanism.
12.3.3
CPU Receiving Unicast Frame
The receiving CPU frame is moved to FDB and the Frame Engine forwards a switch request including the frame
header to Search Engine. After Search Engine decodes the header and determines to forward it to HISC to
process. HISC informs the CPU via a mail, which indicates the handle of FDB. CPU then obtains the frame through
the MDS213. After read the frame from FDB, CPU will inform HISC to release the FDB. Finally, HISC passes the
release command to Frame Engine to release the FDB accommodated CPU frame.
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Zarlink Semiconductor Inc.
MDS213
12.3.4
Data Sheet
CPU Receiving Multicast frame
The MDS213 is capable of receiving a multicast packet for a combination of local ports, remote ports, and also the
CPU. In this case, the received frame includes multicast destination ports on a remote device, and also the CPU.
The Frame Engine moves the multicast frame to FDB and then form a switch request including the frame header to
Search Engine. Since the frame involves CPU, the Search Engine passes the request to HISC for further process.
HISC informs CPU via a mail, which indicates the handle of FDB. In parallel, the Search Engine sends back a
switch response and ask Frame Engine to forward the frame to destinations ports. Frame Engine will perform the
same multicast forwarding as mentioned above.
CPU read the frame from FDB via MDS213. After read the frame from FDB, CPU will inform HISC to release the
FDB. Finally, HISC passes the release command to Frame Engine to release the FDB accommodated CPU frame.
Note that the Frame Engine won't release FDB until it receives the release signal from HISC and also the counter is
reduced to zero. That means all the ports and CPU have read out the frame.
13.0
Port Mirroring
13.1
Features
The received or transmitted data of any 10/100 port in any MDS213 chip, connected by Port Mirror signal pins,
PM_DO and PM_DI, can be chosen to be mirrored to the "Mirror Port." The mirror port can be the first port in a
MDS213 with RMII or a dedicated mirror port with MII, driven by the pin, PM_DO[0:1]. Once the first RMII port of a
chip is selected to be the mirror port, it cannot be used to serve as a data port. The configuration of port mirroring is
shown in the following diagram, based on the current evaluation board design.
PM_DO[1:0]
PM_DENO
MDS213
MDS213
Chip 1
Chip 0
Port
PM_DO[1:0]
PM_DENO
PM_DI[1:0]
PM_DENI
4 FE
RMII
4 FE
RMII
4 FE
RMII
1
GMII
0123
Mirror
port
4567
8 9 10 11
12
4 FE
RMII
4 FE
1
4 FE
GMII
RMII
RMII
13 14 15 16 17 18 19 20 21 22 23 24 25
Mirror
port
MII
PHY
Mirror
Port
Port 0 can be RMII mirror port and mirror port 1-11.
Port 13 can be a RMII mirror port and mirror port 0-11, 14-24.
Dedicated MII mirror port can mirror port 0-11, 13-24.
Figure 19 - Configuration of Mirror Port for MDS213
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Zarlink Semiconductor Inc.
MDS213
13.2
Data Sheet
Physical Pins
There are 6 related pins to Port Mirroring functions:
•
PM_DI [1:0]
Port Mirroring Input Data Bit [1:0]
Receive the mirrored data signal from the remote MDS213.
•
PM_DENI
Port Mirroring Data Enable signal for PM_DI Input
Provide Data Enable signal for PM_DI signals
•
PM_DO[1:0]
Port Mirroring Output Data Bit [1:0]
Transmit the mirrored data signal to remote MDS213.
•
PM_DENO
Port Mirroring Data Enable Output.
Provide Data Enable signal for PM_DO signals
Refer to Figure 20 for connecting above pins.
13.2.1
Setting Register For Port Mirroring
The APMR register controls the mirrored port, the designated mirroring port. The definition of the register is shown
as follows:
13.2.1.1
APMR- Port Mirroring Register
31
15 14 13 12
0
11
MP Rx/ L/R
0 Tx
Mirror Port
Bit [11:0]Mirr_Port10/100 port is chosen to be mirrored, (port bit map)
Bit [12] Local/RemoteIndicate the mirrored port from local or remote device.
0=local 1=remote
(Note: Not support 1G port Mirroring.)
Note that at most only one of bit in Bit[11:0] can be set to 1.
Bit [13] Rx/TxWhether mirror receiving data or transmitting data
0= Transmission Mirroring, 1=Receiving Mirroring
Bit [14] MP0Mirror to Port 0 (Default=0)
MP0=1 Mirror to port 0
MP0=0 Mirror not go to port 0. i.e., to PM_DO pins.
Bit [31:15]Reserve
We use examples to illustrate how to set the APMR register. The following examples are based on the configuration
of Figure 20.
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Example 1: Mirroring port 1 to port 0 and Mirror transmission direction.
For Chip 0
Set APMR[11:0]=0x002; mirrored port= 1
Set APMR[12]=0 ; local mirrored port
Set APMR[13]=0; Transmission mirroring
Set APMR[14]=1; Port 0 is the mirroring port
For Chip 1:
Don't Care
Example 2: Mirroring port 1 to port 13 and Mirror receiving direction.
For Chip 0
Set APMR[11:0]= 0x002; mirrored port= 1
Set APMR[12]=0 ; local mirrored port
Set APMR[13]=1; receiving mirroring
Set APMR[14]=0; Port 0 is not the mirroring port
For Chip 1:
Set APMR[11:0]=0x000
Set APMR[12]=1 ; remote mirrored port
Set APMR[13]=Don't careBit[13] has meaning only in the chip of mirrored port
Set APMR[14]=1; Port 13 is the mirroring port
Example 3: Mirroring port 1 to MII Mirroring port Mirror receiving direction.
For Chip 0
Set APMR[11:0]= 0x002; mirrored port= 1
Set APMR[12]=0 ; local mirrored port
Set APMR[13]=1; receiving mirroring
Set APMR[14]=0; Port 0 is not the mirroring port
For Chip 1:
Set APMR[11:0]= 0x000
Set APMR[12]=1 remote mirrored port
Set APMR[13]= Don't careBit[13] has meaning only in the chip of mirrored port
Set APMR[14]=0Port 13 is not the mirroring port
Note that CPU needs to find out the speed of the mirrored port and configures the mirroring port to the same speed.
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Zarlink Semiconductor Inc.
MDS213
14.0
14.1
Data Sheet
Virtual Local Area Networks (VLAN)
Introduction
A Virtual LAN (VLAN) is a logical, independent workgroup within a network. The members in this workgroup
communicate as if they are sharing the same physical LAN segment. VLANs are not limited by the hardware
constraints that physically connect traditional LAN segments to a network. As a result, VLANs can define a network
into multiple logical configurations.
14.2
VLAN Implementation
The MDS213 based VLAN implementation allows up to 256 VLANs in one switch. By using explicit or implicit VLAN
tagging and the GARP/GVRP protocol (defined in IEEE 802.1p and 802.1Q), VLANs may span across multiple
switches. A MAC address can belong to multiple VLANs, and a switch port may be associated with multiple VLANs.
14.2.1
Static Definitions of VLAN Membership
The MDS213 defines VLAN membership based on ports. Port based VLANs are organized by physical port
numbers. For example, switch ports 1, 2, 4, and 6 can be one VLAN, while ports 3, 5, 7, and 8 can be another
VLAN. Broadcasts from servers within each group would only go to the members of its own VLAN. This ensures
that broadcast storms cannot cause a network meltdown due to traffic volume.
14.2.2
Dynamic Learning of VLAN Membership
While port based VLAN only defines static binding between a VLAN and its port members, the MDS213's
forwarding decision needs to be based on the following:
•
•
A destination MAC address and its associated port ID for a unicast frame, or
The associated VLAN of a source MAC address, if the destination MAC address is unknown or it is a
multicast/broadcast frame. To make valid forwarding and flooding decisions, the MDS213 learns the
relationship of the MAC address to its associated port number and VLAN ID and builds up the internal
Switching Database at run-time for further use.
14.2.3
Dynamic Learning of Remote VLAN
In addition to adding and deleting VLAN member ports through network management tools statically, a MDS213
based switch can also support GVRP (GARP VLAN Registration Protocol). GVRP allows for dynamic registration of
VLAN port members within a switch and across multiple switches. In addition to supporting the dynamic update of
registration entries in a switch, GVRP is also used to communicate VLAN registration information to other VLANaware switches, so that a VLAN member can be covered by a wide range of switches in a network. GVRP allows
both VLAN-aware workstations and switches to issue and revoke VLAN memberships. VLAN-aware switches
register and propagate VLAN membership to all ports belonging to the active topology of the VLAN.
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Zarlink Semiconductor Inc.
MDS213
14.2.4
Data Sheet
MDS213 Data Structures For VLAN Implementation
0
63
FDB
Frame Data Buffers
Transmission queues
FDB block must start from 0
Programmable Size
External RAM
CPU/HISC Mailing List
VLAN ID Table
(4k entry, 8B/entry)
VLAN MAC Table
(2k entry, 256/128/64 bit)
MAX
1/2MB, 1MB or 2MB
Byte Byte Byte ByteByte ByteByte Byte
7
6
5
4
3
2
1
0
Programmable Size
32KB
64, 32 or 16KB
(up to the number of
supported VLAN)
Figure 20 - Data Structure Diagram
14.2.4.1
VLAN ID Table
The VLAN ID Table is used by Search Engine for unicast frames. The base address of this table is specified by
VIDB subfield in BIT[5:0] of VTBP register.
The contents of this table are set up by the MDS213's microcode through the command of CPU software at the time
of VLAN creation and deletion. The VLAN ID Table covers the entire 4K VLAN ID space, and is used by the Search
Engine to map the VLAN ID into an internal VLAN Index. It also includes port membership and port tagging
information for each VLAN. Each VLAN ID entry is 8 bytes long, and the total size of the VLAN ID Table is 32KB.
The VLAN ID table must be located at the 32K boundary.
Byte 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1 9 8 7 6 5 4 3 2 1 0
1098765432109876543 210
0 Index[3: C V P12P11 P10 P9 P8 P7 P6 P5 P4 P3 P2 P1 T S
0]
P28
P17P16
Index[7:
4
4]
Figure 21 - VLAN ID Table
Bit[1:0] P0VLAN Status for Port 0
Bit [0]SThis port is a member of this VLAN
Bit [1]TTagout
Bit[3:2] P1 VLAN status for Port 1
….
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Bit [26]VVLAN is Valid
Bit [27]CCPU is a member of this VLAN
Bit [31:28]1st byte: VLAN Index [3:0], 2nd byte: VLAN Index [7:4]
Note: P0 to P12 are used to identify the ports on the first chip, while P16 to P28 are used to identify the ports on the
second chip.
14.2.4.2
VLAN MAC Table
The size of this table is defined by VLMS subfield in BIT[8:7] of VTBP register. The base address of this table is
specified by VMACB subfield in BIT[15:9] of VTBP register. The VLAN MAC Table contains all associated VLANs
for each MAC Address learned by MDS213, and is used by the software to keep track of every MAC and its
associated VLANs. The contents of this table are set up by the Search Engine at the reception of incoming frames,
if the Search Engine is not fully occupied. When the Search Engine is too busy handling frame forwarding
decisions, microcode in the HISC engine will be assigned the setup new MAC to VLAN associations. Rows in this
table can be cleared up by microcode through a CPU software command during VLAN deletion or port link down. A
row in this table will be cleared and a new bit set up by the MDS213's microcode, when the port change of a MAC
address is detected.
There is a total of 2K entries in this table, one entry per MAC. Each entry may consist of 256, 128 or 64 bits, one bit
per VLAN. The total size of the VLAN Table may be 64, 32 or 16KB. This table must be located at the boundary of
its own table size.
MAC
handle
0 1 2 3 .........................
100
256
0
1
2
3
.
.
.
.
.
.
.
..
.
.
2K
VLAN
ID
Figure 22 - VLAN MAC Table
This table can be accessed by CPU software through CPUIRCMD and CPUIRDAT registers.
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Zarlink Semiconductor Inc.
MDS213
14.2.4.3
Data Sheet
VLAN Port Mapping Table (VMAP)
The VLAN Port Mapping Table (VMAP) is an internal table within the MDS213. It contains 256 entries, one for each
VLAN, identified by an internal VLAN Index. The contents of this table are set up and maintained by CPU software
during VLAN creation, deletion and VLAN port membership modification. VMAP is used by Frame Engine to
forward multicast or destination unknown unicast frames to multiple ports simultaneously.
13 12
27 26 25
31
RE
VLAN Port Enable [12:0]
0
TAG Enable [12:0]
Bit [12:0]VLAN Tag Enable [12:0]One bit for each Ethernet MAC Port
0 = disable, 1 = enable
Bit [25:13]VLAN Port Enable [12:0]One bit for each Ethernet MAC Port, identifying the ports
associated with each VLAN. 0 = disable, 1 = enable
Bit [26]RE Remote Ports Enable: Indicate some members in the remote
device.0=disable, 1=enable
Bit [31:27]Reserve
14.2.4.4
Port VLAN ID (PVID) Register
This register defines the Port VLAN ID (PVID) and priority for each port. PVID needs to be set up by CPU software,
and is used by MDS213 to decide the port's VLAN ID and priority if the incoming packet is VLAN untagged.
31
24 23
16 15
13 12
11
Priority
8 7
0
Port VLAN ID
Bit [11:0]:Port VLAN ID (PVID),
Bit [12]:Reserved
Bit [15:13]: Priority
Bit [31:16]:Reserved
15.0
IP Multicast
15.1
Introduction
IP Multicast permits an IP host (source) to transmit a single IP packet to multiple IP hosts (receivers). IP
Multicasting allows a source to send only one copy and the network ensures delivery to each member of the
specified multicast group. Network bandwidth is allocated more efficiently, as multiple copies of the same frame are
not transmitted between common ports.
The packet destined to an IP multicast group address determines the set of recipients. Hosts may choose to be
members of a number of multicasts, and hence select the multicast packets they wish to receive. They may
subscribe or unsubscribe to these multicast groups dynamically, using the Internet Group Management Protocol
(IGMP) that support automatic multicast group membership. IGMP is configured to create, update, and/or remove
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MDS213
Data Sheet
dynamic multicast group entries between switches and multicast clients and servers. RFC 1112 specifies the
protocols and behaviour for IP Multicasting.
The MDS213 supports up to 255 IP Multicast Groups and treats them as extensions of the VLAN operation. No
additional hardware is needed, since the IGMP operates on the hardware already provided for VLAN functionality.
IGMP packets are identified by the Search Engine and are passed to the external CPU for processing, when the
destination MAC address is 01-00-5E-xx-xx-xx, Protocol field value equals 2 and the destination IP address is
224.0.0.x. The external CPU then instructs the HISC to setup IP Multicast entries for the MAC Addresses in the
Switch Database Memory, the VLAN Table, and the MCT-VLAN Table. The HISC builds and maintains an MCTVLAN and a VLAN Table for IP Multicast Groups in the Frame Buffer Memory.
When an IP Multicast packet is received, it is identified by a specific class of Multicast Destination MAC addresses,
where the high-order bits indicate use of IGMP, and the low-order bits indicate the specific IGMP Group Identifier.
The MDS213 searches the MCT VLAN Association Table for destination MAC addresses, using the IGMP or the
IGMP Group Identifier stored in the MCT, to obtain port membership for the IP Multicast Group. The Search Engine
forwards the packet to each port associated with the IP Multicast Group. Where no address is found, the HISC
firmware updates the MCT-VLAN to include this address.
The Multicast Buffer Control Register (MBCR) allows the configuration of multicast frames to be forwarded, the
number of buffers reserved for receiving remote multicast frames, the number of multicast frames allowed, and the
multicast forwarding threshold.
15.2
IGMP and IP Multicast Filtering
IP multicast filtering optimizes switched network performance by limiting multicast packets to only be forwarded to
ports containing multicast group membership instead of flooding all ports in a subnet (VLAN).
The Internet Group Management Protocol (IGMP) runs between hosts and their immediate neighboring multicast
routers. The mechanism of the protocol allows a host to inform its local router that it wishes to receive transmissions
addressed to a specific multicast group. Routers, also, periodically query the LAN to determine if known group
members are still active.
Based on the group membership information, learned from the IGMP, a router is able to determine which (if any)
multicast traffic needs to be forwarded to each of its "leaf" sub-network. Multicast routers use this information, in
conjunction with a multicast routing protocol, to support IP multicasting across the Internet.
The MDS213 based switch supports IP Multicast Filtering by passively snooping on the IGMP Query. The IGMP
Report packets are transferred between IP Multicast Routers and IP Multicast host groups to learn the IP Multicast
group members within each VLAN actively sending out IGMP Query messages soliciting IP Multicast group
members. They thus learn the location of multicast routers and member hosts in multicast groups within each
VLAN.
Since IGMP is not concerned with the delivery of IP multicast packets across sub-networks, an external IP multicast
router will be needed if the IP multicast packets have to be routed across different IP sub-networks.
15.3
Implementation in MDS213
The MDS213 supports up to 255 IP Multicast Groups and treats them as an extension of the VLAN operation. No
additional hardware is needed, since IP Multicast Switching/Filtering already operates in hardware provided for
VLAN functionality.
IGMP packets are identified by the Search Engine and are passed to the external CPU for processing, when the
destination MAC address is 01-00-5E-xx-xx-xx, Protocol field value equals 2 and the destination IP address is
224.0.0.x. The external CPU then instructs the HISC to setup an MCT entry for this IP Multicast Address in the
Switch Database Memory. If this is a new IP Multicast group, it sets up an entry in the VLAN Port Mapping Table by
itself.
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MDS213
Data Sheet
Whenever an IP Multicast data packet (destination MAC = 01-00-5e-xx-xx-xx, and destination IP address is within
the range of 224.0.1.0 and 239.255.255.255) is received, the Search Engine will use the MCT table to look up the
IP Multicast address of the incoming packet. Frame Engine then will use the result from the search (VLAN Index) to
forward this IP Multicast packet to its member ports according to the VLAN Port Mapping Table.
15.3.1
MCT Table
The MCT table is an internal table within the MDS213 chip that has a total of 2K entries. The CPU setups and read
the table one entry at a time through microcode in the HISC. There are two types of overlapped MCT entries, one
used for layer-2 MAC address based unicast switching, and the other for IP Multicasting.
15.3.1.1
MCT Structure For Unicast Frame
The MCT table is used by the Search Engine to forward unicast frames. By looking up a destination MAC address
from this table, the associated port number is found and used for packet forwarding decisions. The content of the
table is set up by the Search Engine at the reception of an incoming frame, if the Search Engine is not fully
occupied. When the Search Engine is too busy handling frame forwarding decisions, microcode in the HISC engine
will be assigned to do the learning job by setting up new MAC to Port associations.
An entry in this table can be setup by microcode in HISC through a CPU software command for static layer-2 packet
filtering based on either the source or destination address. An entry can be cleared by microcode in the HISC
through a CPU software command, during VLAN deletion, port link down, or when it is aged out. It will also be
cleared and a new one set up when a port change of a MAC address is detected.
Byte 3 3 2 2 2 2 2 2 2
109876543
0
MAC3
S
4
S
P
8
12
T:
2221111111 1119876543210
2109876543 210
T
MAC2
MAC1
MAC0
D Port number
MAC5
MAC4
Next Handle
Time stamp, used for aging. Set to 1 after MAC is found, and cleared to 0 when aged.
MAC[5:0]:MAC Address
S:
Source MAC address filtering
D:
Destination MAC address filtering
SP: Transmit Speed. 1- Gbps, 0-100Mbps
Next Handle: Pointer to the next entry in a hashed link list.
15.3.2
MCT structure for IP Multicast Packet
An IP Multicast entry in the MCT table can be setup or torn down by microcode in HISC through a CPU software
command for IP Multicasting. Whenever an IP multicast data packet is received, the Search Engine will use this
table to look up the IP Multicast address and VLAN ID of the incoming packet. If the IP Multicast address is found,
an internal VLAN Index from the MCT entry will be used by the Search Engine and Frame Engine to forward the IP
Multicast packet to the specific IP Multicast group members in a VLAN. If not, the packet will be forwarded to the
VLAN it belongs to.
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MDS213
Data Sheet
Byte 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1 9 8 7 6 5 4 3 2 1 0
1098765432109876543 210
0
VLAN ID
IP1
IP0
4
C
VLAN Index
IP3
IP2
P
U
8
Next Handle
12
VLAN ID:The VLAN ID this IP Multicast group is located in.
IP[3:0]:IP Multicast Address
VLAN Index:Internal VLAN Index used to identify this IP Multicast group
CPU:1: Switch CPU is part of this IP Multicast group
Next Handle: Pointer to the next entry in a hashed link list.
16.0
Quality of Service (QOS)
Quality of Service (QoS) provides the capability to reserve bandwidth throughout the network. This is particularly
useful for sending voice or video over the switched network. In a switched Ethernet environment, this is only
possible with Resource Reservation Protocol (RSVP), a Layer 3 protocol. In a Layer 2 switch, QoS, referred as
Class of Service (CoS) by the IEEE 802.1Q standard, provides the capability to prioritize certain tasks on the
network. This is done at the application level, where applications can set the priority when the frame is created. The
MDS213 classifying Ethernet frames according to their IEEE 802.1p/Q VLAN priorities. There are three bits in the
VLAN ID reserved to designate the priority of a packet.
Each port stores its transmission jobs into four transmission scheduling queues, one for each priority. Before
transmitting, a port selects a queue from which a transmission job is read. The transmission job points to a frame
stored in memory that is fetched and transmitted. The four queues, representing four classes of traffic, are selected
using a weighted round robin (WRR) strategy. The relative service rates among these queues are programmable
such that bandwidth can be allocated according to classes. This ensures that critical applications get a fair share of
bandwidth, even when the network is overloaded.
The Search Engine recognizes the IEEE 802.1p priority tag and classifies each incoming frame into four internal
priority classes: P0, P1, P2 and P3, in decreasing priority. Since the IEEE 802.1p/Q allows up to eight priorities, a
programmable mapping allows the user to map the 802.1p priority to the internal priority tag via register AVTC.
16.1
Weighted Round Robin Transmission Strategy
Frames of four different priorities are transmitted according to a weighed round robin (WRR) strategy. The WRR is
a modified form of the fair round-robin strategy, in which the server visits the queues in turn. In a fair round-robin
strategy, the server treats all queues equally and visits them with identical frequency. In a WRR, the queues are
weighted, i.e., one queue may be visited more frequently than another. These weighs are programmable via
register AXSC, in which the service rate ratio between two adjacent classes of traffic is set.
In register AXSC, setting QSW0=2, QSW1=QSW2=1 gives the service ratio 8:2:1:1, which is a good start for most
LAN switches. This ratio allocates 67% = 8/12 of bandwidth to P0, 16% = 2/12 of bandwidth to P1, and P2 and P3
each receives 8.3% = 1/12 of bandwidth, assuming all frames have identical frame length.
16.2
Buffer Management Functions
The MDS213 stores frame data in frame buffers. The number of frame buffers in a system is the maximum number
of frames a device can store. When all frame buffers are used, incoming frames cannot enter the memory and are
discarded. Without buffer management, a congested port causes a backlog of frames that eventually occupy all
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
frame buffers. The MDS213 features buffer management functions that prevent a single type of traffic from
depleting all frame buffers. The buffer manager limits the number of frames each destination port can store, thereby
preventing congested ports from occupying all the buffers and blocking incoming frames.
The buffer manager examines the destination port of every frame stored, and increments a counter associated with
this destination port. These buffer counters keep track of the number of buffers occupied by frames destined to
each port. If the counter reaches a threshold, incoming frames destined for the associated port will be dropped.
This threshold is programmable via register BCT and BCHL. Register BCT allows the user to program two
thresholds, one high and one low. The user specifies a threshold, high or low, for each port in register BCHL.
The buffer manager also prevents multicast frames from occupying all frame buffers. A programmable threshold,
register MBCR, limits the number of multicast frames stored in memory. In another word, buffers are reserved for
unicast frames.A multicast forwarding job points to a multicast frame in memory fetched and forwarded by the
Frame Engine across the XPipe to the remote device. The Frame Engine can only forward a handful of multicast
frames simultaneously across the XPipe. Excess multicast forwarding jobs are stored in an internal FIFO, called the
MC-Forwarding-FIFO. If the MC-Forwarding-FIFO is full, incoming multicast frames can no longer be forwarded to
the remote device.
The MDS213 has a programmable option to recognize IP multicast (IPMC) frames. By default, IPMC frames are
treated equally with Layer 2 multicast frames. This option gives IPMC privilege, in terms of buffer allocation, over
regular Layer 2 multicast frames. In a broadcast storm, Layer 2 multicast frames are discarded before IPMC
frames. The system has the flexibility to recognized a programmable IPMC MAC address signature, set by registers
IPMCAS0, IPMCAS1, IPMCMSK0 and IPCMMSK1. If a programmable option, DCR2, bit 26, is turned on, the
system reserves space in the MC-Forwarding-FIFO for IPMC frames. This ensures that Layer 2 multicast frames do
not block IPMC frames.
17.0
Port Trunking
Port trunking groups a set of 8 MDS213 10/100Mbps physical ports into one logical link; however, all ports in the
trunk group must be within the same access device, and each port can only belong to one trunk group. All ports in
the Trunk group must belong to the same VLAN and share the same MAC Address. Each system can support up to
4 groups. Gigabit ports cannot be trunked.
Load distribution for unicast and multicast traffic is done based on a hash key, a hash function of the Source
Address and the Destination Address.
17.1
Unicast Packet Forwarding
A trunked port will need to have its ECR1 MAC Port Configuration Register set by CPU software to contain its
associated Trunk Group ID. Later on, when a new source MAC Address is learned through that port, the Trunk
Group ID will be recorded in the MCT entry by either the Search Engine or the microcode in the HISC. The Trunk
Group ID will be used for forwarding decision when the destination MCT entry of a received packet is found by the
Search Engine, if the status field indicates that the address found is on a Trunk Group.
The Trunk Group ID is used by the Search Engine, along with the "hash key" (3 bits result of a hash operation
between source address and destination MAC address), to access a Trunk Port Mapping Table entry in the internal
RAM. Each entry in this table contains the device and port IDs for the physical port used to transmit this packet.
Software needs to set these entries, using TPMXR and TPMTD registers, to distribute the traffic load across the
ports in the Trunk Group. If the source MAC Address of an incoming packet is on a Trunk Group (based on the MCT
information), the receiving port's TGID will be compared against the Trunk Group ID in the source MCT to decide
whether the source MAC address has moved to another Trunk Group or not.
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MDS213
TG provided by
Search Eng
Data Sheet
Dev ID
(1 bit)
TG
Hash Key
(2 bits)
(3 bits)
Port ID
(4 bit)
Hash Keys
32 entries
.
.
.
.
.
.
Port Mapping Table for MDS213
Figure 23 - Port Mapping Table
In Figure 23, the Trunk Port Mapping Table is 32 entries deep (4 groups * 8 hash entries), and each entry is 5 bits
wide (1-bit device ID, 4-bit port ID), as show in the following format.
17.2
Multicast Packet Forwarding
For multicast packet forwarding, the destination device must determine the proper set of ports to transmit the
packet based on the VLAN Index and Hash Key, generated by the source Search Engine. Two functions are
needed to distribute multicast packets to the appropriate destination ports in a Trunk Group.
1. Selecting a Forwarding Port per Trunk Group:
Only one port per Trunk Group will be used to forward multicast packets. This can be done with a VLAN INDEX
Table and a Forwarding Port MASK Table set up by CPU.
2. Blocking Multicast Packet Back to the Source Trunk:
For multicast forwarding that includes ports in Trunk Groups in the same device as source port, all ports in the same
Trunk Group at the receiving port must be excluded. Otherwise, this multicast packet will be looped back to the
same source Trunk Group. This is achieved through a Trunk Group ID Register that contains 36 bits (36=12x3).
17.2.1
Select One Forwarding Port per Trunk Group
To forward multicast frames, the Frame Engine retrieves the VLAN member ports from one of the 256 entries in the
VLAN Port Mapping Table (VMAP) as described in the VLAN section. By using the Hash Key and the Forwarding
Port Mask table, the Frame Engine can obtain the corresponding FP Mask. The final forwarding ports can then be
determined by the logical AND of the FP Mask and the VLAN Member Port bit map. The Forwarding Port- Mask
Table must be set by the CPU to THKM[0:7] registers beforehand. The format of this table and the method of setting
it up are shown below.
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MDS213
Data Sheet
Forwarding Port MASK Registers
CPU sets up this table as follows:
1. Set up one entry of these registers at a
time until table is exhausted.
2. Set all bits not in any Trunk Group to 1.
3. Set all bits in the Trunk Groups to 0.
4. Pick one forwarding port per Trunk Group
and turn the corresponding bit to 1.
(Each Hash Key may have different forwarding
port, the rule to pick forwarding port is up to
CPU)
(12 bits)
3-bit Hash Key
8 entries in table
FP Mask
VLAN Member Port
AND
Forwarding Ports
Figure 24 - Forwarding Port Mask Table
Two restrictions exist in setting up tables:
1.
When setting up the VLAN Port Mapping Table, all the ports in the Trunk Group must be set to 1, if the
VLAN has ports in any Trunk Group.
2. When setting up the Forwarding Port Mask Table, the CPU software picks only one forwarding port per Trunk
Group.
17.2.2
Blocking Multicast Packets Back to the Source Trunk
For local multicast packets, the Frame Engine needs to block the multicast packets from being sent to the same
Trunk Group as the receiving (source) port. To do it, the Search Engine utilizes the Trunk Group ID (TGID) in ECR1
Register.
The Frame Engine compares the TGID of the source and forwarding ports. If the two TGIDs are the same, the
Frame Engine blocks the forwarding port for this multicast packet. The Switch Engine provides the TGID of the
source port.
Example
The following is an example demonstrating this port trunking scheme for multicast packet forwarding:
4 Trunk Group in a switch:
Group 0: port 0,1,2 in device 0
Group 1: port 4, 5,6 in device 0
Group 2: port 1, 2,3 in device 1
Group 3: port 4, 5,6 in device 1
A multicast packet with VLAN INDEX=5 is received at port 0 of device 0.
The membership of this VLAN:
Device 0: port 0,1,2, 4,5, 6, 7
Device 1: port 1,2, 3, 4,5,6, 8
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MDS213
Data Sheet
Hash Key = 3
Forwarding Port for each group with Hash Key=3,
Port 2 for Group 0
Port 4 for Group 1
Port 3 for Group 2
Port 6 for Group 3
A
N
D
Device 0
Local
0 1 2 3 4 5 6 7 ...........12
0011100111111
1110111100000
Forwarding Port Mask
for Key=3
VLAN Member
for INDEX=5
Forwarding Ports
Turn this port off
since port 2 has
0000100100000
the same TGID of
Multicast packet received at port 0 of device 0 source port 0
VLAN IDX=5, Hash Key=3
0010100100000
Device 1
Remote
0 1 2 3 4 5 6 7 ...........12
1001001111111
0111111010000
A
N
D
0001001010000
Figure 25 - Multicast Packet Forwarding Example
17.3
MAC Address Assignment
In MDS213, there are three ways to assign the MAC address to each port. All the ports in the same device share
the 44 MSBs, MAC[47:4], which are shown in ADAR0 and ADAR1 registers, while the 4 LSBs, MAC[3:0] are
specified in ADAOR0 and ADAOR1 registers for port 0-port 7 and port 8-port 12, respectively.
The method to assign the 4 LSBs MAC[3:0] can be assigned as follows:
•
•
•
If the switch does not support Port Trunking, MAC[3:0]= port number
If the switch supports multiple MAC addresses and Port Trunking, the ports in the same Trunk Group share
the same MAC[3:0]. The value of MAC[3:0] is assigned by the Trunk Group (TG) Table.
If the switch supports only a single MAC address, all the 4 LSBs of MAC will be set the same value in
ADAOR0 and ADAOR1 register.
18.0
Register Definitions
18.1
Register MAP
All registers are grouped into sets:.
•
•
•
•
•
•
•
•
Device Configuration
Buffer Memory Interface
Frame Control Buffer
Queue Management
Switching Control
Link List Management
Access Control Functions
MAC Port Control
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MDS213
Data Sheet
Access Control:
W/R = These register bits may be read from and written to by software
W/-- = These register bits may be written to by software, but not read. Write Only
(--/R) = These register bits may be read but not written to by software. Read Only
Latched and held bits
Clear bits
Permanently set bits
All registers are 32-bit wide. They are classified in the following tables:
Tag
Description
Address
W/R
1. Device Configuration Registers (DCR)
GCR
Global Control Register
7C0
W/--
DCR0
Device Status Register
7C0
--/R
DCR1
Signature & Revision & ID Register
7C4
W/R
DCR2
Device Configuration Register
7C8
W/R
DCR3
Interface Status Register
7CC
--/R
MEMP
Memory Packed Register
7DC
W/R
Interrupt Status Register - Unmasked
7E0
--/R
ISRM
Interrupt Status Register - Masked
7E4
--/R
IMSK
Interrupt Mask Register
7E8
W/R
Interrupt Acknowledgement Register
7EC
W/--
2. Interrupt Controls
ISR
IAR
3. Buffer Memory Interface
MWARS
Memory Write Addr. Reg. - Single Cycle
780
W/--
MRARS
Memory Read Addr. Reg. - Single Cycle
784
W/--
MWARB
Memory Burst Write Address Register
788
W/--
MRARB
Memory Burst Read Address Register
78C
W/--
MWDR
Memory Write Data Register
790
W/--
MRDR
Memory Read Data Registers
794
--/R
VTBP
VLAN ID & MAC member Table Base Pointer
798
W/R
MBCR
Mulitcast Buffer Control Register
79C
W/R
RAMA
RAM block access Register
7A0
W/R
Reserve
Must Set to "0x0001 0008"
7B8
W/R
Reserve
Must Set to "0x0001 0000"
7BC
W/R
Table 8 - MDS212 Register Map
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MDS213
Tag
Description
Data Sheet
Address
W/R
4. Frame Control Buffers Management
FCBSL
FCB Stack Size Limit
740
W/R
FCBST
Frame Ctrl Buffer Stack - Buffer Low Threshold
744
W/R
Buffer Counter Threshold
74C
W/R
Buffer Counter Hi-Low Selection
750
W/R
BCT
BCHL
5. Queue Management
CINQ
CPU Input Queue
708
W/--
COTQ
CPU Output Queue
70C
-/R
6. Switching Control
HPCR
HISC Processor Control Register
6C0
W/R
HMCL0
HISC Micro-Code Loading Port-Low
6C4
W/R
HMCL1
HISC Micro-Code Loading Port-High
6C8
W/R
HPRC
HISC Priority Control Register
6D0
W/R
MCS0R
Micro Sequence 0 Register
6D4
W/R
MCS1R
Micro Sequence 1 Register
6D8
W/R
Flooding Control Register
6DC
W/R
MCT Aging Timer
6E0
W/R
TPMXR
Trunk Port Mapping Table Index Register
6E4
W/--
TPMTD
Trunk Port Mapping Table Data Register
6E8
W/R
Pacing Time Regulation
6EC
W/R
MCT Threshold & Counter Register
6F0
W/R
Link List Status Register
680
W/R
AMBX
Mail Box Access Port
684
W/R
AFML
Free Mail Box List Access Port
688
W/R
FCR
MCAT
PTR
MTCR
7. Link List Management
LKS
8. Access Control Function Group 1 (Chip Level controls)
AVTC
VLAN Type Code
648
W/R
AXSC
Transmission Scheduling Control Register
64C
W/R
ATTL
Transmission Timing & Threshold Control Register
650
W/R
AMIIC
MII Command Register
654
W/--
AMIIS
MII Status Register
658
--/R
Flow Control Ram Input Address
65C
W/--
AFCRID0
Flow Control Ram Input Data
660
W/R
AFCRID1
Flow Control Ram Input Data
664
W/R
AFCRIA
Table 8 - MDS212 Register Map (continued)
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MDS213
Tag
Address
W/R
Flow Control Register
670
W/R
AMAR0
Multicast Addr. For MAC Control Frames Byte [3,2,1,0]
674
W/R
AMAR1
Multicast Addr. For MAC Control Frames Byte [5,4]
678
W/R
AMCT
MAC Control Frame Type Code Register
67C
W/R
ADAR0
Base MAC Address Register - Byte [3,2,1,0]
600
W/R
ADAR1
Base MAC Address Register - Byte [5,4]
604
W/R
ADAOR0
MAC Offset Address Register Port [7:0]
608
W/R
ADAOR1
MAC Offset Address Register Port [12:8]
60C
W/R
Timer for SOF Check
610
W/R
AFCOFT10
Flow Control Off Time for 10Mbps port
614
W/R
AFCOFT100
Flow Control Off Time for 100Mbps port
618
W/R
AFCOFT1000
Flow Control Off Time for Giga port
61C
W/R
AFCHT10
Flow Control Holding Time for 10 port
620
W/R
AFCHT100
Flow Control Holding Time for 100 port
624
W/R
AFCHT1000
Flor Control Holding Time for Giga port
628
W/R
Port Mirroring Register
5C0
W/R
Protocol filtering Register
5C4
W/R
THKM0
Trunking Forward Port Mask 0 (hash key=0)
5C8
W/R
THKM1
Trunking Forward Port Mask 1 (hash key=1)
5CC
W/R
THKM2
Trunking Forward Port Mask 2 (hash key=2)
5D0
W/R
THKM3
Trunking Forward Port Mask 3 (hash key=3)
5D4
W/R
THKM4
Trunking Forward Port Mask 4 (hash key=4)
5D8
W/R
THKM5
Trunking Forward Port Mask 5 (hash key=5)
5DC
W/R
THKM6
Trunking Forward Port Mask 6 (hash key=6)
5E0
W/R
THKM7
Trunking Forward Port Mask 7 (hash key=7)
5E4
W/R
IPMCAS0
IP multicast MAC address signature Low Register - Byte
[3:0]
5E8
W/R
IPMCAS1
IP multicast MAC address signature High Register - Byte
[5:4]
5EC
W/R
IPMCMSK0
IP multicast MAC address Mask Low Register - Byte[3:0]
5F0
W/R
IPMCMSK1
IP multicast MAC address Mask High Register - Byte[5:4]
5F4
W/R
CFCBHDL
FCB Handle Register for CPU
580
--/R
CPUIRCMD
CPU Internal RAM Command Register
584
W/R
CPUIRDAT0
CPU Internal RAM Data Register - 0
588
W/R
AFCR
ACKTM
Description
Data Sheet
9. Access Control Function Group 2 (Chip Level controls)
APMR
PFR
Table 8 - MDS212 Register Map (continued)
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MDS213
Tag
Data Sheet
Description
Address
W/R
CPUIRDAT1
CPU Internal RAM Data Register - 1
58C
W/R
CPUIRDAT2
CPU Internal RAM Data Register - 2
590
W/R
CPUIRRDY
Internal RAM Read Ready for CPU
594
--/R
LED Register
598
W/R
LEDR
10. Ethernet MAC Port Control Registers - (substitute [N] with Port Number, N = {0..12})
ECR0
MAC Port Control Register
[N*4]0
W/R
ECR1
MAC Port Configuration Register
[N*4]4
W/R
ECR2
MAC Port Interrupt Mask Register
[N*4]8
W/R
ECR3
MAC Port Interrupt Status Register
[N*4]C
--/R
ECR4
Status Counter Wrap Signal
[N*4+1]0
--/R
PVIDR
PVID Register
[N*4+2]4
W/R
Table 8 - MDS212 Register Map (continued)
18.2
Register definitions
18.2.1
Device Configuration Register
18.2.1.1
GCR - Global Control Register
Access:
Zero-Wait-State,
Address:
h7C0
31
Direct Access,
24 23
20 19
Write only
16 15
12 11
8
7
4
SYN
Bit [2:0]
Op-Code
3
2
0
Op-Code
3-bit Operation Control Code
Op-Code
Command
Description
000
Clr RST
Clear Device Reset: - Allows state machines to exit from RESET state
and to initialize their internal control parameters if necessary.
001
RESET
Device Reset: -- Resets all internal state machines of each device and
stays in RESET state (except the Processor Bus Interface logic).
010
EXEC
011
--
No-Op
1XX
--
No-Op
Execution: -- Allows state machines to start their normal operations.
Table 9 - Global Control Register
Bit [7:4]
SYN bits, reserved for HISC Usage.
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MDS213
18.2.1.2
Data Sheet
DCR0 - Device Status Register
Access:
Zero-Wait-State,
Address:
h7C0
Direct Access,
Read only
31
1
0
Status
Bit [1:0]
Status
2-bit Operation Control Code
* Power-up default = 00
Status
State
Description
00
INIT
01
RESET
10
EXEC
Initialization: Device is in idle state pending for system
software initialization.
Device Reset: Device is in RESET state.
Execution: Device is under normal operation.
Table 10 - Device Status Register
Bit [31:2]
Reserved
18.2.1.3
DCR1 - Signature, Revision & ID Register
Access:
Non-Zero-Wait-State, Direct Access,
Address:
h7C4
31
25 24
20 19
Write/Read
16 15
Dev_ID
8 7
4
3
Signature
Bit [3:0]
Device Revision Code
Bit [7:4]
Reserved
Bit [15:8]
Signature
Bit [19:16]
Reserved
Bit [24:20]
DEV_ID
Bit [31:25]
Reserved
18.2.1.4
12 11
5-bit Device ID (Read/Write)
DCR2 - Device Configuration Register
Non-Zero-Wait-State,
Address:
h7C8
31
27 26 25
IP
Boot Strap MC
Direct Access,
Write/Read
9 8 7 6 5 4 3 2 1 0
22 21 20 19 18 17
FE and MAC
0
Rev
8-bit Device Signature
Access:
2
SE Configuration
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MT ML
IP SC
MDS213
Data Sheet
Bit [1:0]
SC
System Clock Rate
00= 100Mhz
10=90Mhz
Default = 00
01 = 120Mhz
11= 80Mhz
Bit [2]
IP
IRQ output polarity control
0 = active low output
Power-up default =0
1 = active high output
Bit [3]
SM
System Configuration mode
0=Nonblocking (For MDS213,
always equal to 0)
1=Blocking
SRAM Memory Characteristics
Bit [4]
Bit [6:5]
ML
MT
Bit [8:7]
Buffer Memory Level, which can be either 2 chips or 4 chips.
0 = 2 memory chips
1 = 4 memory chips
Default = 0
Memory Chip Type
00 = 64K x 32-bit
10 = 256K x 32-bit
Default = 01
01 = 128K x 32-bit
11 = 512K x 32-bit
Reserved
Search Engine Configuration
Bit [9]
SE_AGEN
Aging enable, if which is true, the old MCT can be aged out.
Default = 1
1 = enable aging
0 = disable aging
Bit [11:10]
HM
Hashing Mode, each of which uses
different bits of MAC address to come
up with each bit of hashing key.
Default = 00
00=mode 0
0=mode 2
01=mode 1
11=mode 3
Bit [13:12]
HS
Hashing Size
00= 8
10= 10
Default = 01
01= 9
11= TDB
Bit [14]
VSW
VLAN Aware Switch
0 = VLAN Unaware
Default = 0
1 = VLAN Aware
Bit [15]
NoIPM
No IP Multicast
1 = IP Multicast Disable
Default = 1
0 =IP Multicast Enable
Bit [16]
GLN
Global Learning Disable, where CPU
shall disable global learning before
look into it as a whole piece.
1 = Learning Disable
Default = 0
Partial Synchronization enable for
MAC Table
0= Fully Synchronization for MCT
table
Default=0
Bit [17]
Partial Syn
enable
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0 = Learning Enable
1= Partial Synchronization
for MCT table
MDS213
Bit [18]
Data Sheet
Reserved
Frame Engine and MAC Configuration
Bit [19]
FE_AGEN
Aging enable. If true, the memory
resources, occupied by the old
message, will free up.
Default = 1
0 = disable aging
1 = enable aging
Power-up default =0
1 = Forward oversize
frames
Bit [20]
FOF
Forward Oversize Frames
0 = Discard oversize frames
Bit [21]
Dec_Buffer_CNT
Decrements buffer counter. When the software writes "1" to this
bit, the Frame Engine decreases buffer counter by one.
Bit [22]
BC_EN
Buffer counter enable
0 = Disable (no head of line
control
1 = enable
Bit [23]
STA_EN
Status counter enable
0 = collect status in counter
disable
1 = collect status in
counter enable
Bit [24]
SEL_PCS
Default=0
1 = Use internal PCS in
the chip
0 = Use external PCS
Bit [25]
Link_GT
TX LED will be off when the link is
down and this bit is 0
0 = Gate 0ff TX_En when Link
down
Default =0
1 = Not Gate off TX_En
when Link down
Bit [26]
IPMC
IP Multicast privileges enable: IP
multicast traffic has a privilege over
regular multicast traffic.
0= disable
Default=0
1= enable
Boot Strap Determine by the bootstrap value.
Bit [27]
BMOD
Bit [28]
RW
Control Bus Mode (Read only bit) Must BE 0
CPU Read/Write Control Polarity Selection Read only bit
0 = R/W#
Bit [29]
SWM
1 = W/R#
Switching Mode
(Read only bit)
0 = Managed mode
Default=1
1 = Unmanaged mode
Bit [30]
PSD
Master Device Enable (Read only bit)
1 =Primary
Default=1
0 = Secondary
Bit [31]
MRDY
Option of merge the RDY and B_RDY as
one pin
(Read only bit)
0 =merged pin
Default=1
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1 = separated pins
MDS213
18.2.1.5
Data Sheet
DCR3 - Interfaces Status Register
Access:
Zero-Wait-State,
Address:
h7CC
31
Direct Access,
25 24
21 20
Read only
16 15
12 11
8 7
4 3 2 1 0
Mem_Stat
Que_Stat
Bit [3:0]
Reserved
Bit [7:4]
Mem_Stat
Buffer Memory Interface Status
Bit [4]
BB
Buffer Memory Busy, CPU interface is busy accessing Memory
Bit [5]
RE
Read FIFO Empty, the FIFO that CPU interface reads is empty
Bit [6]
WE
Write FIFO Empty, the FIFO that CPU writes is empty
Bit [7]
Res.
Reserved
Bit [11:8]
Que_Stat
Queue Manager Interface Status
Bit [8]
IQ_Rdy
CPU Input Queue is ready for CPU to write into queue
Bit [9]
IQ_Full
CPU Input Queue is full
Bit [11:10] Reserved
Bit [31:12] Reserved
18.2.1.6
MEMP - Memory Packed Register
Access:
Non-Zero-Wait-State,
Address:
h7DC
31 - 30
Direct Access,
Write/Read
17 16 15
8 7
NP
WCL
5
0
RCL
Bit [7:0]
RCL
Read Cycle Limit (Unit is system Clock).
Threshold of reads cycle time.
Default=16
Bit [15:8]
WCL
Write Cycle Limit (Unit is system Clock).
Threshold of writes cycle time.
Default=16
Not Packed
NP=0 Enable the feature of memory read/write
packed.
Default=0
NP=1 Disable, memory
access will be a pure
round-robin scheme.
Bit [16]
NP
Bit [31:17]
Reserved
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MDS213
18.2.2
Data Sheet
Interrupt Control Registers
Four 32-bit Control Registers.
ISR
Interrupt Status RegisterIdentify the unmasked interrupt request sources
Access:
Zero-Wait-State,
Address:
h7E0
ISRM
Direct Access,
Masked Interrupt Status Reg.Identify the sources of interrupt with masking
• Access:
Zero-Wait-State,
• Address:
h7E4
IMSK
Read only
Direct Access,
Read only
Interrupt Mask RegisterDefines the interrupt sources to be masked
• Access:
Non-Zero-Wait-State,
Direct Access,
Write/Read
• Set bits to 1 to mask the corresponding interrupt sources
• Address:
IAR
h7E8
Interrupt Acknowledgment Reg.Clear the interrupt request bits
• s Access:
Non-Zero-Wait-State,
Direct Access,
Write only
• s Set bits to 1 to clear the corresponding interrupt sources
• s Address:
h7EC
All 4 registers have a common register format and bit assignment
31
25 24 23
MC
T
11 10
MAC_Port Interrupt
9
FM
L
Interrupt MAC port mapping bit/port
8
7 6 5 4 3
HI MA
SC IL
2
1
0
BPFC DB BS CP
IL R R Q
Interrupt Source
Interrupt Sources (The following bits need to be redefined.)
Bit [0]
CPU_Q_Out
CPU output queue level interrupt
Bit [1]
BSR
Bad switch response
Bit [2]
Double R
Double Release
Bit [3]
FCB_Low
FCB Low
Bit [4]
HISC_BP
HISC instruction pointer matched with Breakpoint Register
Bit [5]
Reserved
Bit [6]
Reserved
Bit [7]
MAIL_ARR
Mail arrived from HISC
Bit [8]
HISC_TO
HISC Timeout Interrupt
Bit [9]
Reserved
Bit [10]
FML_Av
Link manager informs CPU that at least 16 Free Mail entry available
after CPU encounters empty Free Mail list situation.
Bit [23:11] MAC_PORT
Interrupt from MAC ports
Bit [11] for Port 0, Bit [12] for Port 1 … Bit [23] for port 12, port 12 is a
Giga port
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MDS213
Bit [24]
MCT
Data Sheet
Search Engine found looped MCT Chain.
Bit [31:25] Reserved
Note: MAIL_ARR, CPU_Q_Out and interrupts cannot be cleared by the CPU. They will be cleared whenever their
queues are emptied.
18.2.3
Buffer Memory interface register
18.2.3.1
MWARS - Memory Write Address Register - Single Cycle
Access:
Zero-Wait-State,
Address:
h780
28 27 26
31
BE[3:0]
via FIFO,
Write
3 2 1 0
24 23 22 21 20
00001
I/E
SP LK
Address MA[20:3]
Bit [0]
LK
Lock Flag (for internal memory only)LK=0 UnlockLK=1 Lock
Bit [1]
SP
Swap Byte Order
Bit [20:2]
MA [20:2]
Buffer memory address Bit [20:2] - (Bit [1:0] = 00)
Bit [21]
Reserved
Bit [22]
I/E
Indicates the Address is Internal or External memory
I/E=0 Internal memory
Bit [27:23] Count
Must be 00001
Bit [31:28] BE [3:0]
Byte lane enables
I/E=1 External memory
CPU Bus Type
Bit [31]
Bit [30]
Bit [29]
Bit [28]
Little Endian
BE [3]
BE [2]
BE [1]
BE [0]
Big Endian
BE [0]
BE [1]
BE [2]
BE [3]
18.2.3.2
MRARS - Memory Read Address Register - Single Cycle
Access:
Zero-Wait-State,
Address:
h784
31
28 27
BE[3:0]
via FIFO,
Write
3 2 1 0
24 23 22 21 20
00001
Address MA[20:2]
I/E
Bit [0]
LK
Lock Flag memory
Bit [1]
SP
Swap Byte Order
Bit [20:2]
MA [20:2]
Buffer memory address Bit [20:2] -
Bit [21]
Reserved
Bit [22]
I/E
LK=0 Unlock
SP LK
LK=1 Lock
(Bit [1:0] = 00)
Indicate the Address is Internal or External memory
I/E=0 Internal memory
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I/E=1 External memory
MDS213
Bit [27:23] Count
Must be 00001
Bit [31:28] BE [3:0]
Byte lane enables
18.2.3.3
Data Sheet
Address Registers For Burst Cycle
Two 32-bit burst size registers share a common format
•
MWARB
• Address:
•
Memory Address Register - Burst Write (in D-words) - Maximum 8 D-words
h788
MRARB
Memory Address Register - Burst Read (in D-words) - Maximum 8 D-words
• Address:
Access:
h78C
Zero-Wait-State,
31
28 27
via FIFO,
3 2 1 0
24 23 22 21 20
Count
Bit [0]
Write
LK
Address MA[20:2]
I/E
SP LK
Lock Flag
LK=0 Unlock
Bit [1]
SP
Bit [2]
Reserved
Bit [20:2]
MA [20:2]
Bit [21]
Reserved
Bit [22]
I/E
LK=1 Lock
Swap Byte Order
Buffer memory address Bit [20:2] -
(Bit [1:0] = 00)
Indicate the Address is Internal or External memory
I/E=0 Internal memory I/E=1 External memory
Bit [27:23] Count
Count = Burst Size in double words Burst size for internal memory is up to
8 D-words. Burst size for external memory is up to 16-Dwords
00001 = 1 D-word,
……01000 = 8 D-word
01111 = 15 D-word
10000= 16 D-word
Valid value range for internal memory is {1 to 8}
Valid value range for external memory is {1 to 16}
Caution: When setting Count = 16, the Starting address has to be in the Q-word boundary. That is MA[2]=0.
Bit [31:28]
Reserved
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18.2.3.4
Data Sheet
Memory Read/Write Data Registers
Four 32-bit data registers share a common format
•
MWDR
Memory Write Data Register
• Access: Zero-Wait-State,
• Address: h790
•
MRDR
via FIFO,
Write only
Memory Read Data Register
• Access: Zero-Wait-State,
• Address: h794
Direct Access,
Read only
Byte Order depends on CPU types
•
Little Endian CPUs
31
24 23
Byte [3]
•
8 7
16 15
Byte [2]
0
Byte [0]
Byte [1]
Big Endian CPUs
31
24 23
Byte [0]
18.2.3.5
8 7
16 15
Byte [1]
0
Byte [3]
Byte [2]
VTBP - VLAN ID Table Base Pointer
Access: Non-Zero-Wait-State,
Direct Access,
Write/Read
Address:h798
31
17 16 15
11 10
VMACB
Bit [5:0]
VIDB
9
8
7
VLMS
6
5
0
VLAN ID BASE
VLAN ID Table Base, serves as [20:15] bits of address.
(VLAN ID Table is 32KB)
Bit [6]
Reserved
Bit [8:7]
VLMS
The size of VLAN MAC Table Default=11
00= reserved
01=16K (for 64 VLANs)
10=32K (for 128 VLANs)11=64K (for 256 VLANs)
Bit [15:9]
VMACB
VLAN MAC Table Base, serves as [20:14] bit of address.
This table indicates the association of MAC address and VLAN
Bit [31:16]
Reserved
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MDS213
18.2.3.6
MBCR - Multicast Buffer Control Register
Access:
Non-Zero-Wait-State,
Address:
h79C
31
Direct Access,
Data Sheet
Write/Read
MCTH
5 4
11 10
22 21 20 19
MAX_CNT_LMT
RMC_BUF_RSV
0
MAX_MC_FD
Bit [4:0]
MAX_MC_FD
Maximum Number of Multicast Frames allowed for forwarding
Bit [10:5]
RMC_BUF_RSV
Number of buffers reserved for receiving remote Multicast Frames
Bit [19:11] MAX_CNT_LMT
Maximum Number of Multicast Frames allowed per device
Bit [21:20] MCFTH
Multicast Forwarding Threshold: Watermark for forwarding FF to drop
regular multicast packet if IPMC bit in DCR2[26] is ON. CPU can set four
level watermarks, which are programmable
00= 25%
01=50%
10= 75%
11= 100%
Bit [31:22] Reserved
18.2.3.7
AMA - RAM Counter Block Access Register
Access:
Non-Zero-Wait-State,
Address:
h7A0
Direct Access,
Write/Read
RAM counter block contains 13 counter blocks (one for each port) Port 0 counter block starts at address 0.) The
size of each block is 16 double words, which consist of total 30 statistic counters. has total The size and type of
each counter is referred to the register ECR4.
CPU uses this register to access the specified statistic counter by setting the start address of RAM counter block
and the length.
31
16 15 14
11 10
W/
R
4 3
ST_ADR
0
BST_CNT
Bit [3:0]
BST_CNT
Read/write burst (length) of RAM Block. (Unit = 1double words)
Bit [10:4]
ST_ADR
Read/Write Start Address.
Bit [14:11]
Reserved
Bit [15]
W/R
RAM Block Access Write/Read indicator
1 = Write
0 = Read
Bit [31:16] Reserved
Note: The access range is equal to from ST_ADR to END_ADR= S_ADR+ BST_CNT. The END_ADR cannot cross
the boundary of each port block, i.e., 8 double words.
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18.2.3.8
Reserve Register 1
Access
Non-Zero-Wait-State
Address:
h7B8
Direct-Access
31
Data Sheet
Write/Read
16 15
4 3 2 1 0
0x0001
0x0008
Must be set to "0X00010008"
18.2.3.9
Reserve Register 2
Access
Non-Zero-Wait-State
Address:
h7BC
31
Direct-Access
Write/Read
16 15
25
3 2 1 0
0x0001
0x0000
Must be set to "0X00010000"
18.2.4
Frame Control Buffers Management Register
18.2.4.1
FCBSL - FCB Queue
Access:
Non-Zero-Wait-State,
Address:
h740
31
Direct Access,
Write/Read
18 17
11 10
Aging Timer Base
Bit [10:0]
0
Max # of FCB Buffer
Defines Max # of FCB Buffers
Size Range: 1 entry, to 1024 entries
Bit [17:11]
Aging Timer Base
Defines the time interval between scanning of FCB Buffers for aged
buffers
Aging Time = (Number of valid FCB Buffers* Aging Timer Base) msec
18.2.4.2
FCBST - FCB QUEUE - Buffer Low Threshold
Access:
Non-Zero-Wait-State,
Address:
Direct Access,
Write/Read
h744
31
6 5
0
BLowTH
Bit [5:0]
Buf_Low_Th
Buffer Low Threshold - The number of frame control buffer handles left
in the Queue to be considered as running low and trigger the interrupt
to the CPU.
Bit [31:6]
Reserved
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MDS213
18.2.4.3
BCT - (FCB) Buffer Counter Threshold
Access
Non-Zero-Wait-State
Address:
h74C
Direct-Access
31
Data Sheet
Write/Read
10 9
19
Hi Limit
Bit[9:0]
Low_Limit
0
Low Limit
Low limit number of frames to each destination port (i.e., Source port
limits the # of FCB used by each destination port)
Bit[19:10]
HI_Limit
High limit number of frames to each destination port (i.e., Source port
limits the # of FCB used by each destination port)
18.2.4.4
BCHL - Buffer Counter Hi-low Selection
Access
Non-Zero-Wait-State
Address:
Direct-Access
Write/Read
h750
31
25
13 12
Rp_Hi_Low Sel
Bit[12:0]
Lp_Hi_Low Sel
0
Lp_Hi_Low Sel
Selection for Low or High Limit of Buffer Counter for Local device
13 bits maps to 13 ports in Local Device
1 = select hi limit
Bit[25:13]
Rp_Hi_Low Sel
0 = select low limit
Selection for Low or High Limit of Buffer Counter for Remote device
13 bits maps to 13 ports in Remote Device
1 = select hi limit
18.2.5
0 = select low limit
Queue Management Register
18.2.5.1
CINQ - CPU Input Queue
Access:
Non-Zero-Wait-State,
Address:
h708
Direct Access,
Write only
31
0
32-bit data from CPU input queue
Note: Check IQ_RDY=1 in DCR3 (Interface Status Register) before writing into CPU Input Queue
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18.2.5.2
COTQ - CPU Output Queue
Access:
Non-Zero-Wait-State,
Address:
h70C
Direct Access,
Data Sheet
Read only
31 30
0
CPU Output Queue Entry
Bit [30:0]
31-bit CPU Output Queue Entry
Bit [31]
Status queue is ready
18.2.6
Switching Control register
18.2.6.1
HPCR - HISC Processor Control Register
Access:
Non-Zero-Wait-State,
Address:
h6C0
Direct Access,
Write/Read
31
3 2 1
0
RS LD HT
Bit [0]
HT
Halt the HISC processor from execution Not Apply for non-managed
mode (It can be fixed in next cut.)Power-up default = 1
Bit [1]
LD
Switch the Micro-Code Memory from instruction fetch mode to downloading mode
Bit [2]
RS
Reset IP to 0 - (Write only bit)
(This bit is auto reset to 0 after IP is reset to 0)
Bit [31:3]
Reserved
RS
LD
HT
State
Description
1
0
1
INIT
0
0
1
HALT
Halt State: -- Stopped HISC execution, waiting for HT=0.
0
1
X
LOAD
Micro-Code Loading State: -- Stopped HISC execution, increment IP for
every Wr/Rd to HMPC
1
0
0
START
Start State: -- Reset IP=0, and start HISC execution.
0
0
0
EXEC
Execution State: -- Continue HISC execution without reset IP.
1
1
X
--
Initialization State: -- Stopped HISC execution, reset IP to 0.
Illegal State.
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MDS213
Data Sheet
18.2.6.2
HMCL0 - HISC Micro-code Loading Port - Low
Access:
Non-Zero-Wait-State,
Address:
h6C4
Direct Access,
Write/Read
Loading micro code into HISC.
31
19
0
HISC Instruction Word [31:0]
Bit [31:0]
HISC Instruction Word [31:0]
HISC Instruction Word has total 40 bit-wide. Needs to
be broken into two registers.
18.2.6.3
HMCL1 - HISC Micro-code Loading Port - High
Access:
Non-Zero-Wait-State,
Address:
h6C8
Direct Access,
Write/Read
31
0
8 7
HISC Instruction [39:32]
Bit [7:0]
HISC Instruction Word [39:32]
Bit [31:8]
Reserved
18.2.6.4
MS0R Micro Sequence 0 Register
Access:
Zero-Wait-State,
Address:
h6D4
31
Direct Access,
24 23
Write/Read
16 15
8 7
0
DataBit[31:0]
Bit [31:0]
Data Bit [31:0] to the sequencer RAM
(The length of Micro Sequence Data is 54-bit, Need to be broken into tow registers)
18.2.6.5
MS0R Micro Sequence 1 Register
Access:
Zero-Wait-State,
Address:
h6D8
31
29 28
Direct Access,
Write/Read
0
20 19
Data bit[51:32]
Cnt
Bit [19:0]
Data Bit [51:32] to the sequencer RAM
Bit [31:29] CNT Control bits
000
(Write only bits)
NOP
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MDS213
001
Load
010
Restart Ptr
011
IncAdr
100
Halt
101
UnLoad
110
UnHalt
Data Sheet
Bit [28:20] Reserved
18.2.6.6
Flooding Control Register
Access:
Non-Zero-Wait-State,
Address:
h6DC
31
Direct Access,
Write/Read
16 15 14
24 23
M2CR
87
Time
Base
Unicast to CPU rate
Bit [7:0]
12 11
U2MR
0
Multicast to CPU rate
Multicast to CPU Rate
Restricts the number of frames within the Time window defined in bit[15:12]
Bit [11:8]
U2MR
Unicast to Multicast Rate
Restricts the number of flooding unicast frames within the Time window
Bit [14:12] Time Base Defines the time window used by M2CR and U2MR
Bit [15]
000 = 100us
001 = 200us 010 = 400us
011 = 800us
100 = 1.6ms
101 = 3.2ms 110 = 6.4ms
111 = 100us
Reserved
Bit [23:16] U2CR
Unicast to CPU Rate
Restricts the number of frames within the Time window defined in bit[15:12]
Bit [31:24] Reserved
18.2.6.7
MCAT - MCT Aging Timer
Access:
Non-Zero-Wait-State,
Address:
h6E0
31
Direct Access,
Write/Read
0
20 19
MCT Aging Timer
Bit [19:0]
When the value is reached, it ages out
Default=0 msec (unit=msec) Must be configured to not zero value.
Suggestion value: 5msec.
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Data Sheet
18.2.6.8
Tpmxr – Trunk Port Mapping Table Index Register
Access:
Non-Zero-Wait-State,
Address:
h6E4
Direct Access,
Write/Read
For Trunk port mapping Table pointer
31
0
8 7
Entry Index
Bit [7:0]
8-bit Table entry Index
Bit [31:8]
Reserved
Value set to 0
18.2.6.9
TPMTD - Trunking Port Mapping Table Data Register
Access:
Non-Zero-Wait-State,
Address:
h6E8
Direct Access,
Write/Read
31
5
4 3
0
DV
Bit [3:0]
Port ID
Trunking port
Bit [4]
DV
Device ID
Bit [31:5]
Reserved
18.2.6.10
Port ID
PTR - Pacing Time Regulation
Access
Non-Zero-Wait-State
Address:
h6EC
Direct-Access
Write/Read
Use for Pacing traffic to Remote Ports via XpressFlow Pipe or Local transmission
16 15
31
12 11
UC_TM
Bit [3:0]
100_TM
100M port timer
Default =5
Bit [7:4]
g_TM
Gigabit port timer
Default =6
Bit [11:8]
mc_TM
Multicast timer
Default =5
bit[ 15:12]
uc_TM
Unicast timer
Default =5
8
MC_TM
7
4 3
G_TM
0
100_TM
Unit time = 80 nsec.(for 64 Bytes Frame.)
Note that Frame Engine determine the tic value dependent upon the frame. If short frame, it takes above value. For
long frame (> 64 frame), it will double the above value as the reference.
Bit [31:16] Reserved
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18.2.6.11
Data Sheet
MTCR - MCT Threshold & Counter Register
Access:
Non-Zero-Wait-State,
Address:
h6F0
Direct Access,
31
Write/Read
22 21
0
11 10
MCT threshold
Bit [10:0]
Reserved
Bit [21:11]
MCT Threshold
Bit [31:22]
Reserved
18.2.7
Alert system when free MCT entries are below this threshold
Link List Management
18.2.7.1
LKS - Link List Status Register
Access:
Zero-Wait-State,
Address:
h680
Direct Access,
Read only
31
Bit [0]
4 3
2
1
0
Mail Box is not ready for CPU to send entry to HISC
1=Not Ready0=Ready
Bit [1]
Free Mail Box is not ready for CPU to put entry into
1= Not Ready0=Ready
Bit [2]
CPU gets Mail from HISC
1= Ready0=Not Ready
Bit [3]
Free Mail Box has entry for CPU to get
1=Ready 0=Not Ready
Bit [31:4]
Reserved
18.2.7.2
AMBX - Mail Box Access Port
Access:
Zero-Wait-State,
Address:
h684
Direct Access,
Write/Read
In write mode, CPU sends Mail to HISC
In Read mode, CPU receives Mail from HISC
31 30
21 20
2 1
Entry Handle
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0
0
0 0
MDS213
Bit [20:0]
Data Sheet
Entry handle, the bit [2:0] always 2'b000
Bit [29:21] Reserved
Bit [30]
Link List is Empty. (Read only)
Bit [31]
Link List is Ready. (Same as bit [0] of LKS register) (Read only)
18.2.7.3
AFML - Free Mail Box List Access Port
Access:
Zero-Wait-State,
Address:
h688
Direct Access,
Write/Read
2 1
21 20
31 30
0
Entry Handle
Bit [20:0]
0
0 0
Entry handle, the bit [2:0] always 2'b000
Bit [29:21] Reserved
Bit [30]
Link List is Empty. (Read only)
Bit [31]
Link List is Ready.
(Same as bit [1] of LKS register) (Read only)
18.2.8
Access Control Function
18.2.8.1
AVTC - VLAN Type Code Register
Access:
Non-Zero-Wait-State,
Address:
h648
Direct Access,
31
Write/Read
16 15
P7
P6
P5
P4
P3
P2
P1
0
P0
VLAN Type Code
Bit [15:0]
2-byte VLAN Type Code defined by IEEE 802.1Q VLAN Standard
Bit [31:16]
Priority 4 level priority denoting by 2-bit for each
Mapping 8 level VLAN priorities to 4 level internal priorities.
18.2.8.2
AXSC - Transmission Scheduling Control Register
Access:
Non-Zero-Wait-State,
Address:
h64C
Direct Access,
Write/Read
31
12 11
QSW2
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8 7
4 3
QSW1
0
QSW0
MDS213
Bit [11:0]
QSW[2:0]
Data Sheet
Transmission Queue Service Weight for queue 2, 1 & 0. (4 bit each)
Defines the service rate for each queue QR0-QR3
QR0 : QR1 : QR2 : QR3
QR0 = QSW0*(QSW1+1)* (QSW2+1)
QR1 = QSW1*(QSW2+1)
QR2 = QSW2
QR3 = 1
Note: Queue 0 has the highest priority. Queue Size is defined in the Queue Control Table
18.2.8.3
ATTL - Transmission Timing Control
Access:
Non-Zero-Wait-State,
Address:
h650
Direct Access,
31
Write/Read
22 21
14 13
TxFIFO Threshold[7:0]
5 4
depart_time
Bit [4:0]
Transmission queue aging time out counter
Bit[13:5]
frame latest departure time
Bit [21:14]
TXFIFOT
0
qmt_cnt
Transmission FIFO Threshold in Bytes (Default =0) Only for 100M ports
Unit=8Bytes
0= Cut Through at the destination 100M port
When the value does not equal zero, it indicates the port cannot start
sending frames out, until the Tx FIFO reaches the threshold or EOF.
18.2.9
MII Serial Management Channel
These registers are part of the Management Module. They allow the upper layer services to communicate with any
one of the PHYs that are connected to the Management Module through the serial interface.
18.2.9.1
AMIIC - MII Command Register
This is a write-only register. The upper layer services write the management frame to be sent to the PHYs into this
register. The MSB (bit 31) is the first bit sent over the serial interface.
Access:
Non-Zero-Wait-State,
Address:
h654
31 30 29 28 27
ST
OP
Direct Access,
18 17 16 15
23 22
PHY_AD
Write only
REG_AD
TA
2 1 0
DATA (16-bit)
Bit [31:30]
ST
Start of frame - always = "01"
Bit [29:28]
OP
Operation code - "10" for read command and "01" for write command
Bit [27:23]
PHY_AD
5-bit PHY Address
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Data Sheet
Bit [22:18]
REG_AD
5-bit Register Address in PHY
Bit [17:16]
TA
Turnaround - "10" for write
Bit [15:0]
DATA
16-bit Write Data to PHY
18.2.9.2
AMIIS - MII Status Register
The upper layer services should read this register for data sent by the PHYs. The lower 16 bits contain data
received by the Management Module
Access:
Non-Zero-Wait-State,
Address:
h658
31
30
RY
Direct Access,
29
Read only
2 1 0
16 15
VD
DATA (16-bit)
Bit [31]
RDY
Data Ready
Bit [30]
VALID
Data Valid
Bit [15:0]
DATA
16-bit Read Data from PHY
Bit [31]
RDY
Bit [30]
VALID
1
1
Data field contains valid data from the PHYs
1
0
Data field contains invalid data from the PHYs
0
X
Data field is not ready to be read by Switch Manager CPU
18.2.10
18.2.10.1
Description
Flow Control Management
AFCRIA - Flow Control RAM Input Address
Access:
Non-Zero-Wait-State,
Address:
h65C
Direct Access,
Write only
31
3 2
0
address
Bit [2:0]
3-bit address for the RAM in MAC storing flow control frame
Usage: Flow Control Frame consists of 64 Bytes. Using AFCRIA and AFCRID0-1, the CPU loads 8 bytes each
time. The CPU specifies the address in AFCRIA and writes the content of 4 bytes in AFCRID0 and 4 Bytes in
AFCRID1. Then repeats the above procedure 8 times to load a whole flow control frame into the Chip.
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18.2.10.2
Data Sheet
AFCRID0 - Flow Control RAM Input Data 0
Access:
Non-Zero-Wait-State,
Address:
h660
Direct Access,
Write only
31
0
Content of Input Flow Control Frame[31:0]
Bit [31:0]
Content of flow control frame [31:0],
Flow Control Frame has 64 bytes and is defined by IEEE
18.2.10.3
AFCRID1 - Flow Control RAM Input Data 1
Access:
Non-Zero-Wait-State,
Address:
h664
Direct Access,
Write only
31
0
Content of Input Flow Control Frame[63:32]
Bit [31:0]
18.2.10.4
Content of flow control frame [63:32]
AFCR - Flow Control Register
Access:
Non-Zero-Wait-State,
Address:
h670
31
Direct Access,
Write/Read
16 15 14 13 12
10 9
XN F AE XON_Th
E
d
Bit [9:0]
0
****
Reserved
Bit [12:10] XON_ThdDefines the minimum # of free Frame Buffers before transmitting XON flow control frame.
Bit [13]
Queue Aging Enable
TX queue aging function enable
Bit [14]
Flush Enable
When stack is full, enable flush procession
0 = disable
Bit [15]
XON Enable
1 = enable
Full Duplex XON enable
0 = disable
1 = enable
Bit [31:16] Reserved
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18.2.10.5
Data Sheet
AMAR[1:0] - Multicast Address Reg. For MAC Control Frames
This 6-byte MAC Address is stored in two 32-bit registers
•
•
•
•
AMAR0
MAC Address Byte [3:0]
Address: h674
AMAR1
MAC Address Byte [5:4]
Address: h678
Access:
Non-Zero-Wait-State,
31
Direct Access,
24 23
87
MAC 2
MAC 3
AMAR0
Write/Read
16 15
AMAR1
18.2.10.6
0
MAC 1
MAC 0
MAC 5
MAC 4
AMCT - MAC Control Frame Type Code Register
Access:
Non-Zero-Wait-State,
Address:
h67C
Direct Access,
24 23
31
Write/Read
8 7
16 15
0
Frame Type
•
2-byte MAC Control Frame Type Code defined by IEEE 802.3X Full Duplex Flow Control Standard
18.2.10.7
ADAR [1:0] - Base MAC Address Registers
The 6-byte MAC Address is stored in two 32-bit registers
•
•
•
•
ADAR0
MAC Address Byte [3:0]
Address: h600
ADAR1
MAC Address Byte [5:4]
Address: h604
Access:
Non-Zero-Wait-State,
31
AMAR0
Direct Access,
24 23
MAC 3
Write/Read
87
MAC 1
MAC 5
AMAR1
•
•
•
11
16 15
MAC 2
0 0 0 0
These two registers define the base MAC address of the device.
Bit [3:0] of Byte 0 (MAC5) is always set to 0.
MAC address for each port is defined by
• MAC Address for Port n = Base MAC Address + MAC Offset [n] where n = {0..12}
• MAC Offset[n] is defined by the following registers
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MAC 0
MAC 4
0
MDS213
18.2.10.8
Data Sheet
ADAOR0 - MAC Offset Address Register 0
MAC Offset Address for Port [7:0], 4-bit per port
Access:
Non-Zero-Wait-State,
Address:
h608
31
28 27
Direct Access,
24 23
20 19
Write/Read
16 15
12 11
8 7
4 3
0
Port7_offset Port6_offset Port5_offset Port4_offset Port3_offset Port2_offset Port1_offset Port0_offset
Bit [3:0]
MAC Offset address for Port 0
Bit [7:4]
MAC Offset address for Port 1
Bit [11:8]
MAC Offset address for Port 2
Bit [15:12]
MAC Offset address for Port 3
Bit [19:16]
MAC Offset address for Port 4
Bit [23:20]
MAC Offset address for Port 5
Bit [27:24]
MAC Offset address for Port 6
Bit [31:28]
MAC Offset address for Port 7
Usage: There are three ways to assign the MAC address to each port. All ports in the same device share the 44
MSBs, MAC[47:4] in ADAR[0:1], while the 4 LSBs, MAC Offset [3:0] can be assigned as follows:
1.
In a managed system, if the device does not support port trunking, MAC_Offset[3:0]= the port number.
2.
In a managed system where device supports port trunking, the ports in the same trunk group shares the same
MAC[3:0]. The value of MAC[3:0] is assigned by the smallest port number in the Trunk Group.
3.
In a managed system, if BIT [18] of DCR2, SMAC=0, all ports are assigned to a single MAC.
4.
In an unmanaged system, MAC[3:0] is fixed for all devices (i.e., only one MAC[3:0] address for the whole
system).
18.2.10.9
ADAOR1 - MAC Offset Address Register 1
MAC Offset Address for Port [12:8], 4-bit per port
Access:
Non-Zero-Wait-State,
Address:
Direct Access,
Write/Read
h60C
31
20 19
16 15
Port12_offset
Bit [3:0]
MAC Offset address for Port 8
Bit [7:4]
MAC Offset address for Port 9
Bit [11:8]
MAC Offset address for Port 10
Bit [15:12]
MAC Offset address for Port 11
Bit [19:16]
MAC Offset address for Port 12
Bit [31:20]
Reserved
12 11
Port11_offset
8 7
Port10_offset Port9_offset
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4 3
Port8_offset
MDS213
18.2.10.10
Data Sheet
ACKTM - Timer For SOF Checking
Access:
Non-Zero-Wait-State,
Address:
h610
Direct Access,
Write/Read
31
0
10 9
XOFF_CKTM
Bit [9:0]
XOFF_CKTM
The time out value to check SOF after XOFF
Bit [31:10] Reserved
Note that the purpose of this timer is to avoid continuously sending the XOFF frames. The XOFF Frame is triggered
by the incoming frames when no resources are available in the DS chip. Ideally, after the first XOFF frame is sent
out, we expect no frames to be received until we send out the XON frame. However, the connected device may not
interpret XOFF frames correctly (or may react slowly) and still keep sending data frames to this congested port. In
this case, the congested port will want to send another XOFF frame each time another frame is received. To avoid
this scenario, we set the ACKTM timer to prevent the congested port from sending XOFF frames for every incoming
frame in congestion period before the timer expires.
18.2.10.11
AFCHT10 - Flow Control Hold Time Of 10Mbps Port
Access:
Non-Zero-Wait-State,
Address:
h620
31
Direct Access,
Write/Read
0
16 15
HBK_TM_10
Bit [15:0]
HBK_TM_10
Holding time to remote station for 10Mbps port when the chip
detects the head of line blocking counter has run out. The holding
time value is embedded in the flow control frame sent to the remote
station.
Bit [31:16] Reserved
18.2.10.12
AFCHT 100 - Flow Control Hold Time Of 100Mbps Port
Access:
Non-Zero-Wait-State,
Address:
h624
31
Direct Access,
Write/Read
0
16 15
HBK_TM_100
Bit [15:0]
HBK_TM_100
Holding time to remote station for 100Mbps port when the chip
detects the head of line blocking counter has run out. The holding
time value is embedded in the flow control frame sent to the remote
station.
Bit [31:16] Reserved
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18.2.10.13
Data Sheet
AFCHT1000 - Flow Control Hold Time of Giga Port
Access:
Non-Zero-Wait-State,
Address:
h628
31
Direct Access,
Write/Read
0
16 15
HBK_TM_G
Bit [15:0]
HBK_TM_G
Holding time to remote station for 1000Mbps port when the chip
detects the head of line blocking counter has run out. The holding time
value is embedded in the flow control frame sent to the remote station.
Bit [31:16] Reserved
18.2.10.14
AFCOFT10 - Flow Control Off Time of 10Mbps PROT
Access:
Non-Zero-Wait-State,
Address:
h614
31
24 23
Direct Access,
Write/Read
0
16 15
FL_OFF_10M
Bit [15:0]
FL_OFF_10M
Off time to the remote station for 10Mbps Port when the chip detects
the buffer resource is not available. The OFF time value is embedded
in the flow control frame sent to the remote station.
Bit [31:16] Reserved
18.2.10.15
AFCOFT100 - Flow Control Off Time of 100Mbps PORT
Access:
Non-Zero-Wait-State,
Address:
h618
31
24 23
Direct Access,
Write/Read
0
16 15
FL_OFF_100M
Bit [15:0]
FL_OFF_100M
Off time to remote station for 100Mbps Port when the chip detects
the buffer resource is not available. The OFF time value is
embedded in the flow control frame sent to the remote station.
Bit [31:16] Reserved
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18.2.10.16
Data Sheet
AFCOFT1000 - Flow Control Off Time of Giga Port
Access:
Non-Zero-Wait-State,
Address:
h61c
31
Direct Access,
24 23
Write/Read
0
16 15
FL_OFF_G
Bit [15:0]
FL_OFF_G
Off time to remote station for 1000Mbps Port when the chip detects
the buffer resource is not available. The OFF time value is
embedded in the flow control frame sent to the remote station.
Bit [31:16] Reserved
18.2.11
18.2.11.1
Access Control Function Group 2 (Chip Level)
APMR- PORT MIRRORING REGISTER
Access:
Non-Zero-Wait-State,
Address:
h5C0
Direct Access,
31
15 14
13 12
MP
0
Write/Read
0
11
Rx/ L/R
Tx
Mirror Port
Bit [11:0]
Mirr_Port
The 10/100 port chosen to be mirrored
Bit [12]
Local/Remote
Indicates the mirrored port is from a local or remote device.
0=local
1=remote
(Note Not support 1G port Mirroring.)
Bit [13]
Rx/Tx
Indicates whether the mirror is receiving data or transmitting data
Bit [14]
MP0
Mirror to Port 0
(Default=0)
MP0=1 Mirror to port 0
MP0=0 Mirror not go to port 0
Bit [31:15] Reserved
18.2.11.2
PFR - Protocol Filtering Register
Access:
Non-Zero-Wait-State,
Address:
h5C4
31
Direct Access,
Write/Read
16 15
8 7 6 5 4
3
2
1
0
The Search Engine will provide ingress filtering on a per-devise basis. Each bit of PF register (default value = 0) will
cause packets matching that category to be dropped.
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Bit [7:0]
Protocol Filter for Unicast Frames
Bit [0]
IP - Ethernet II encapsulation
Bit [1]
IP - 802_SNAP encapsulation
Bit [2]
IPX - Ethernet II encapsulation
Bit [3]
IPX - 802_SNAP encapsulation
Bit [4]
IPX - 802.2 encapsulation
Bit [5]
IPX - 802.3_RAW encapsulation
Bit [6]
Other (Packets with unknown encapsulation, or non-IP, non-IPX packets)
Bit [7]
Untagged Frames
Bit [15:8]
Protocol Filter for Multicast Frames
Bit [8]
Multicast IP - Ethernet II encapsulation
Bit [9]
Multicast IP - 802_SNAP encapsulation
Bit [10]
Multicast IPX - Ethernet II encapsulation
Bit [11]
Multicast IPX - 802_SNAP encapsulation
Bit [12]
Multicast IPX - 802.2 encapsulation
Bit [13]
Multicast IPX - 802.3_RAW encapsulation
Bit [14]
Multicast Other (Packets with unknown encapsulation, or non-IP, non-IPX packets)
Bit [15]
Multicast Untagged Frames
Data Sheet
Bit [31:16] Reserved
Usage: There is only one PFR register. For each port there is an enable bit(ECR1 bit 6: IFE- Ingress filter Enable)
which determines whether the settings in PFR are applied to that port.
18.2.11.3
THKM [0:7] - Trunking Forwarding Port Mask 0-7
Eight Trunking Hash Key Mask Registers shared the same format.
•
THKM0
Trunking Forwarding Port Mask 0
Forwarding Port mask for hash key 0
Trunking Forwarding Port Mask 1
Forwarding Port mask for hash key 1
Trunking Forwarding Port Mask 2
Forwarding Port mask for hash key 2
Trunking Forwarding Port Mask 3
Forwarding Port mask for hash key 3
Trunking Forwarding Port Mask 4
Forwarding Port mask for hash key 4
Trunking Forwarding Port Mask 5
Forwarding Port mask for hash key 5
Address:h5C8
•
THKM1
Address:h5CC
•
THKM2
Address:h5D0
•
THKM3
Address:h5D4
•
THKM4
Address:h5D8
•
THKM5
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Data Sheet
Address:h5DC
•
THKM6
Trunking Forwarding Port Mask 6
Forwarding Port mask for hash key 6
Trunking Forwarding Port Mask 7
Forwarding Port mask for hash key 7
Address:h5E0
•
THKM7
Address:h5E4
Access: Non-Zero-Wait-State,Direct Access,Write/Read
31
0
12 11
TK_MSK
Bit [11:0]
TK_MSKPort trunk mask for trunking hash key
Bit [31:12] Reserved
CPU sets up this table as follows:
1. Set all bits not in Trunk Groups to 1
2. Set all bits in the Trunk Group to 0
3. Pick one forwarding port per trunk group and turn the corresponding bit to 1 (Each Hash Key may have different
forwarding ports, the rule to pick forwarding ports is up to the CPU).
Usage: These masks are used to prevent flooded or multicast packets from being transmitted out with more than
one port on a trunk. The Trunking Hash Key is used to select the proper mask (for load distribution). The mask
value will be set up to mask off all but one port within each trunk group.
18.2.11.4
IPMCAS - IP Multicast MAC Address Signature
Usage: For following four registers IPMCAS0, IPMCAS1, IPMCMSK0 and IPMCMSK1, are used to distinguish
between IP multicast traffic and regular multicast. The MAC for IP multicast are h"01:00:5e:00:00:00" to h"
01:00:5e:7f:ff:ff" And the MASK for IPMC is: h"ff:ff:ff:80:00:00".
The 6-byte of IP multicast MAC Address is stored in two 32-bit registers
•
IPMCAS0
IP Multicast MAC Address Byte [3:0]
Address:h5E8
•
IPMCAS1
IP Multicast MAC Address Byte [5:4]
Address:h5EC
Access: Non-Zero-Wait-State,Direct Access,Write/Read
24 23
31
IPMCAS0
MAC 3
16 15
MAC 2
IPMCAS1
•
•
11
87
0
MAC 1
MAC 0
MAC 5
MAC 4
These two registers define the MAC address signature of IP multicast.
Default = h" 01:00:5e:7f:ff:ff"
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18.2.11.5
Data Sheet
IPMCMSK- IP Multicast MAC Address Mask
The 6-byte of IP multicast MAC Mask is stored in two 32-bit registers
•
IPMCAS0
IP Multicast MAC Mask Byte [3:0]
Address:h5F0
•
IPMCAS1
IP Multicast MAC Mask Byte [5:4]
Address:h5F4
Access: Non-Zero-Wait-State,Direct Access,Write/Read
24 23
31
IPMCMSK0
MASK 3
16 15
87
11
MASK 2
0
MASK 1
MASK 0
MASK 5
MASK 4
IPMCMSK1
These two registers define the MAC Mask of IP multicast.
Default = h"ff:ff:ff:80:00:00".
18.2.11.6
CFCBHDL - FCB Handle Register For CPU Read
Access:
Non-Zero-Wait-State,
Address:
h580
Direct Access,
Read only
Usage: When CPU requests a free FDB to write a frame, it must request a free FCB via this register. The register
contains a free handle of FCB, which also pointer to a free FDB.
CPU reads FCB Handle: (When the CPU write FDB, it requires a FDB handle first).
CPU checks CFCBHDL[31],H_RDY ready or not. If so, CPU gets the FCB Handle from CFCBHDL[9:0]
31
0
10 9
H_R
DY
Bit [9:0]
FCB_Handle[9:0]
FCB_HANDLE
FCB Handle Address
Bit [30:10] Reserved
Bit [31]
H_RDY
FCB Handle Ready
0=Not Ready
18.2.11.7
1=Ready
CPU Access Internal RAMs (Tables)
Usage: (refer to section 9 for detail).
The CPU uses the following methods to access the five internal RAMs, including MCID, VLAN port mapping
(VMAP), BM control Table (BMCT), FCB and Transmission Queue control (QCNT).
Registers:
•
•
•
•
•
CPUIRCMD: Command register
CPUIRDAT0: Data Register for specific entry of content Bit[31:0]
CPUIRDAT1: Data Register for specific entry of content Bit[63:32]
CPUIRDAT2: Data Register for specific entry of content Bit[95 64]
CPUIRRDY: Data Read Ready.
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MDS213
Data Sheet
CPU Reads FCB
•
•
•
•
CPU write the read command into CPUIRCMD with FCB Handle, W/R=0. And set C_RDY. Also, set the
table type = FCB, (CPUIRCMD[14]=1)
Frame Engine puts the specified FCB content into CPUIRDATL and CPUIRDATM
Frame Engine Clear C_RDY
Frame Engine set CPUIRRDY[0] to notify CPU that the FCB data is ready to be read.
CPU writes FCB
•
•
•
•
CPU writes the content of FCB into CPUIRDATL and CPUIRDATM
CPU writes the handle of FCB into CPUIRCMD [9:0], set CPUIRCMD [10] = 1,(write CMD), set
CPUIRCMD[31]=1, CMD_RDY and set the Table Index to FCB, (CPUIRCMD[14]=1).
Frame Engine clears CPUIRCMD [31], C_RDY, when Frame Engine reads FCB done
Apply the similar method to access the other four tables.
18.2.11.8
CPUIRCMD - CPU Internal RAM Command Register
Access:
Non-Zero-Wait-State,
Address:
h584
Direct Access,
Write/Read
Command for CPU accesses five internal Tables
31 30
C_R
DY
Bit [9:0]
Bit [10]
16 15 14 13 12
Entry Index
The index of specified entry
Type = MCID(16)
Entry index[3:0]
Type = VMAP(256)
Entry index[7:0]
Type = BMCT(1K)
Entry index[9:0]
Type = FCB(1K)
Entry index[9:0]
Type = QCNT (64)
Entry index[5:0]
W/R
Write or Read the table entry
0=Read
0
11 10 9
QC FC BM VM MC W/
NT B CT AP ID R
Entry Index [9:0]
1=Write
Bit[15:11]
Table bit map
Bit maps of five tables.
Bit[11]
MCID
MCID=1 Use MC ID l Table
Bit[12]
VMAP
VMAP=1 Use VLAN port mapping Table (VMAP)
Bit[13]
BMCT
BMCT=1 Use Buffer Manager Control Table (BM control)
Bit[14]
FCB
FCB=1 Use FCB Table
Bit[15]
QCNT
QCNT=1 Use Transmission Queue control Table (QM control)
Bit [30:16] Reserve
Bit [31]
C_RDY
Command Ready
0=Not Ready
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Zarlink Semiconductor Inc.
1=Ready
MDS213
18.2.11.9
Data Sheet
CPUIRDAT - CPU INTERNAL RAM DATA REGISTER
The 3 data registers are used when CPU reads or writes the content of the specified entry. table
•
CPUIRDAT0
Address:
•
h588
CPUIRDAT1
Address:
•
CPU Internal RAM Data register for Data[31:0]
CPU Internal RAM Data register for Data[63:32]
h58C
CPUIRDAT2
CPU Internal RAM Data register for Data[95:64]
Address:
h590
Access:
Non-Zero-Wait-State,
Direct Access,
Write/Read
31
0
CPIRDAT0
Data[31:0]
CPIRDAT1
Data[63:32]
CPIRDAT2
Data[95:64]
The content is dependent as to the type of table, as describe follows.
Type = MC ID (6bits)
31
CPIRDAT0
Bit [5:0]
0
6 5
MCID[5:0]
MCID
multicast ID FIFO data output
(Note that up to 16 for this version.)
Bit [31:6]
Reserved
Type = VMAP Table (27 bits)
31
CPIRDAT0
Bit [12:0]
13 12
27 26 25
RE
VLAN Port Enable [12:0]
VLAN TAG Enable [12:0]
0
VLAN Port Enable [12:0]
one bit for each Ethernet MAC Port
Identify the ports associated with each VLAN
0 = disable
Bit [25:13] VLAN Tag Enable [12:0]
one bit for each Ethernet MAC Port
0 = disable
Bit [26]
RE
1 = enable
1 = enable
Remote Ports Enable: Indicate some members in the remote
device.
0=disable1=enable
Bit [31:27] Reserved
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Zarlink Semiconductor Inc.
MDS213
Data Sheet
Type = BMCT (12bits)
31
12 11
CPUIRDAT0
Bit [11:0]
0
BM[11:0]
BM
Buffer Management control FIFO Output
BM stores free FCB handles. (FCB handle=0 cannot be used.)
Bit [31:12] Reserved
Type = FCB (56 bits)
31
24 23
CPUIRDAT0
FCB_DATA[31:0]
CPUIRDAT1
Bit [55:0]
0
FCB_DATA[55:32]
FCB
Frame Control Block.
Refer to Chapter 9 for detailed data structure.
Type = QCNT (79 bits)
31
CPUIRDAT0
15 14 13
WrPt[5:0]
CPUIRDAT1
4 3 2
Base[11:0]
ECnt[10:0]
RdPt[9:0]
CV
Cache Queue Entry[16:0]
Que_S [2:0]
WrPT[9:6]
Cache Queue Entry[31:17]
CPUIRDAT2
Bit [2:0]
0
QS[2:0]
Queue size
000=128 entries 001=128*2 entries
111=128*8=1K entries
Each entry contains 4 bytes
Bit [14:3]
Base [11:0]
Base pointer to its Transmission Queue
Bit [25:15] ECnt [10:0]
Entry Count: Total entries in its queue.
Bit [35:26] WrPt [9:0]
Write Pointer
Address_Write_Entry[20:9]=Base[11:0]+WrPt[9:7]
Address_Write_Entry[9:3]= WrPt[6:0]
Address_Write_Entry[2:0]= 0
(The address [2:0] is always equal to 0.)
Bit [45:36] RdPt [9:0]
Read Pointer
Address_Read_Entry[20:9]=Base[11:0]+RdPt[9:7]
Address_Read_Entry[9:3]= RdPt[6:0]
Address_Read_Entry[2:0]= 0 (The address [2:0] is always equal to 0.)
Bit[46]
CV
Cache Valid
CV=1, Cache of Queue Entry QE[31:0] is valid.
Bit[78:47]
QE[31:0]
Cache a queue entry
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MDS213
18.2.11.10
Data Sheet
CPUIRRDY - Internal Ram Read Ready For CPU
Access:
Non-Zero-Wait-State, Direct Access,
Address:
h594
Write/Read
The Frame Engine sets this ready bit to notify the CPU that the requested data is ready to read.
31
1 0
RD
Y
Bit [0]
R_RDY
Bit [31:1]
Reserved
18.2.11.11
Access:
Address:
Data in Data registers is ready for CPU Read
LEDR- LED Register
Non-Zero-Wait-State,
Direct Access,
Write/Read
h598
31 30
28 27 26 25 24 23
SS
LCK
HT
16 15
UDEF3
UDEF2
Bit [7:0]
UDEF1
User defined information status 1 for debug purpose
Bit [15:8]
UDEF2
User defined information status 2 for debug purpose
Bit [23:16] UDEF3
User defined information status 3 for debug purpose
Bit [25:24] HT
Holding time for LED signal (Default=00)
Bit [27:26] LCLK
0
8 7
00=8msec
01=16msec
10=32msec
11=64msec
UDEF1
LED Clock frequency (Default=00)
00= 100M/8=12.5Mhz
01= 100M/16=6.25Mhz
10= 100M/32=3.125Mhz
11= 100M/64-1.5625Mhz
Bit [30:28] Reserve
Bit [31]
SS
Start Shift the status bits out from the master device.
This bit has no effect on the slave chip.
Note: UDEF1-UDEF3 are used for debug purpose. The contents of UDEF1-3 are loaded by CPU and the usage of
these are up to software.
18.2.12
Ethernet MAC Port Control Registers
One set for each Ethernet MAC Port [12:0]
MII related controls applies to Port [1:0] only
Port 12 is always dedicated to GMAC
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MDS213
18.2.12.1
Data Sheet
ECR0 - ECR0 - MAC Port Control Register
Access:
Non-Zero-Wait-State,
Direct Access,
Address:
h0x0*4
x: port n
h000
ECR0_p0
h040
ECR0_p1
h080
ECR0_p2
h0c0
ECR0_p3
h100
ECR0_p4
h140
ECR0_p5
h180
ECR0_p6
h1c0
ECR0_p7
h200
ECR0_p8
h240
ECR0_p9
h280
ECR0_p10
h2c0
ECR0_p11
h300
ECR0_p12
Write/Read
31
3 2 1 0
RP RE X R
R R
Bit [0]
RR
Reset Receiver
Bit [1]
XR
Reset Transmitter
Bit [2]
RE
RX Enable
Bit [3]
RP
RST_PCS, Reset PCS logic (Only apply Gigabit Port)
Port is disabled when both RR & XR bits are set.
18.2.12.2
ECR1 - MAC Port Configuration Register
Access:
Non-Zero-Wait-State,
Address:
h0x1*4x: port number
Direct Access,
h004
ECR1_p0
h044
ECR1_p1
h084
ECR1_p2
h0c4
ECR1_p3
h104
ECR1_p4
h144
ECR1_p5
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Zarlink Semiconductor Inc.
Write/Read
MDS213
h184
ECR1_p6
h1c4
ECR1_p7
h204
ECR1_p8
h244
ECR1_p9
h284
ECR1_p10
h2c4
ECR1_p11
h304
ECR1_p12
31
24 23
Data Sheet
17 16 15
8 7 6 5 4 3 2
0
IFE BKUC T TG ID
E
IFG
Configuration Bits
Trunking
Port Trunking ID Bits
Bit [2:0]
TGID
Group ID
Bit [3]
TE
Trunk Enable
0= Trunk disable
1= Trunk Enable
Unicast Blocking Control Bits
Bit [5:4]
Block_UC_Frame
Instructs the Rx MAC to discard incoming Unicast Frames.
This feature is used by Spanning Tree.
11
Bit [6]
IFE
0X
Blocking, all frames (Default state)
10
Learning but not forwarding
Forwarding all frames
Ingress Filter Enable
Default = 0
Used to enable protocol filtering on a port by port basis. There is
only one Protocol Filtering Register (PFR), but it can be used on
any combination of ports.
0= disable ingress filter 1= enable ingress filter
Physical Layer Control Bits
Bit [7]
10M
10M or 100M; 1=10Mbps 0=100Mbps
Bit [8]
Reserved
Bit [9]
Full_Duplex
Enables full duplex modeDefault =0 - Half Duplex
Bit [10]
FDX_Polarity
Selects the output polarity of Full_Duplex control signal
0 = Low true (Default)
Bit [11]
Int_Lpback
1 = High true
Setting this bit cause internal connect
TXCLK, TXD, TXD[0:3] to RXCLK, RXD, RXD[0:3]
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MDS213
Data Sheet
Default =0 - Disable
Bit [12]
Ext_Lpback
Setting this bit indicate an external loop-back
(connection of TXCLK, TXD[0:3] to RXCLK, RXD[0:3]
are required)
Default =0 -- Disable
Bit [13]
FC_Enable
Flow Control EnableDefault =0 - Disable
When enabled:
•
•
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 MAC Receiver marks all Flow Control Frames.
Receive DMA discards the received Flow Control Frame and send status reports to the Switch Manager for
statistic collection.
When Disabled:
•
•
The MAC Transmitter does not asserts flow control by sending Flow Control frames nor jamming collision.
The MAC Receiver still interprets and processes the Flow-Control frames. The MAC Receiver marks all
Flow Control frames. Receive DMA discards the received Flow Control frames and send a status report to
the Switch Manager for statistic collection.
Bit [14]
Link_Polarity
Selects the input polarity of Link Status signal
0 = Low true (Default)
Bit [15]
Tx_Enable
1 = High true
Enables MAC Transmitter for transmission
Default =0 - Disable
Bit [16]
Reserved
Bit [23:17] IFG
Inter-frame Gap (Default=7'd24)
Use to adjust the inter-frame gap. (Unit =transmit Clock.)
The default is 7'd24, stands for 24 transmit clock (each clock
transmit 4 bits).
Bit [31:24] Reserved
18.2.12.3
ECR2 - MAC Port Interrupt Mask Register
Access:
Non-Zero-Wait-State,
Direct Access,
Address:
h0x2*4
x: port number
h008
ECR2_p0
h048
ECR2_p1
h088
ECR2_p2
h0c8
ECR2_p3
h108
ECR2_p4
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Zarlink Semiconductor Inc.
Write/Read
MDS213
h148
ECR2_p5
h188
ECR2_p6
h1c8
ECR2_p7
h208
ECR2_p8
h248
ECR2_p9
h288
ECR2_p10
h2c8
ECR2_p11
h308
ECR2_p12
Data Sheet
31
2 1 0
Mask
Bit [0]
WAS
If set, the status counter wrap around signal is masked.
Bit [1]
Link_Change
If set, the Link_Up and Link_Down Interrupts are masked.
Bit [31:2]
Reserved
Link Change interrupts are automatically disabled whenever both MAC Transmitter & Receiver are in Reset state i.e. both XR & RR bits are set.
18.2.12.4
Access:
ECR3 - MAC Port Interrupt Status Register
Non-Zero-Wait-State,
Address:h0x3*4
Direct Access,
x: port number
h00c
ECR3_p0
h04c
ECR3_p1
h08c
ECR3_p2
h0cc
ECR3_p3
h10c
ECR3_p4
h14c
ECR3_p5
h18c
ECR3_p6
h1cc
ECR3_p7
h20c
ECR3_p8
h24c
ECR3_p9
h28c
ECR3_p10
h2cc
ECR3_p11
h30c
ECR3_p12
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Read only
MDS213
Data Sheet
31
3
2
1
0
Status
Bit [0]
WAS
Wrapped around signal.
Bit [1]
Link_Change
This bit is set when the MAC determines that the status
of physical link has been changed
Bit [2]
LK_UP
0=Link Down,
1=Link UP
This bit is reset whenever the PHY has identified the lost of
physical link integrity.
Bit [31:3]
Reserved
18.2.12.5
ECR4 - Port Status Counter Wrapped Signal
Access:
Non-Zero-Wait-State,
Direct Access,
Address:
h0x4*4
x: port number
h010
ECR4_p0
h050
ECR4_p1
h090
ECR4_p2
h0d0
ECR4_p3
h110
ECR4_p4
h150
ECR4_p5
h190
ECR4_p6
h1d0
ECR4_p7
h210
ECR4_p8
h250
ECR4_p9
h290
ECR4_p10
h2d0
ECR4_p11
h310
ECR4_p12
31 30
Read only
0
Status Wrapped Signal
B[0].
0-d
Bytes Sent(D)
B[1].
1-L
Unicast Frames Sent
B[2].
1-U
Flow Control Sent
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MDS213
B[3].
2-l
Non-unicast frame sent
B[4].
2-U1
frame send fail
B[5].
2-U2
Alignment Error
B[6].
3-d
Bytes Received (Good or Bad) (D)
B[7].
4-d
Frames Received (Good or Bad) (D)
B[8].
5-d
Total Bytes Received (Good) (D)
B[9].
6-L
Total Frames Received (Good)
B[10].
6-U
Flow Control Frames Received
B[11].
7-l
Multicast Frames Received
B[12].
7-u
Broadcast Frames Received
B[13].
8-L
Frames with length of 64 bytes
B[14].
8-U
Jabber Frames
B[15].
9-L
Frames with length between 65-127 bytes
B[16].
9-U
Oversize Frames
B[17].
A-l
Frames with length between 128-255 bytes
B[18].
A-u
Frames with length between 256-511 bytes
B[19].
B-l
Frames with length between 512-1023 bytes
B[20].
B-u
Frames with length between 1024-1528 bytes
B[21].
C-l
Undersize Frames
B[22].
C-u
Fragment
B[23].
D-l
CRC
B[24].
D-u
Short Event
B[25].
E-l
Collision
B[26].
E-u
Drop
B[27].
F-l
Filtering Counter
B[28].
F-U1
Delay exceed discard counter
B[29].
F-U2
Late Collision
Data Sheet
Note: Each port owns a counter block, containing 16 double words. The 29 bits indicate that each corresponding
counter is wrapping around the signal. The type and location of each counter is specified by the following format.
The format description:
X-Y: X means the relative Physical Address in its counter blocks.
: Y indicates the type of counter it is (Notation "C"= double word read from RAM block)
D: C[31:0] double word counter
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MDS213
Data Sheet
L: C[23:0] 24 bits counter
U: C[31:24] 8 bits counter
U1: C[23:16] 8 bits counter
U2: C[31:24] bits counter (the same as notation "U")
l: C[15:0] 16 bits counter
u C[31:16] 16 bits counter
18.2.12.6
PVID Register
Access:
Non-Zero-Wait-State,
Direct Access,
Address:
h0x9*4
x: port number
Write/Read
For Default VLAN ID
h024
PVIDR_p0
h064
PVIDR _p1
h0a4
PVIDR _p2
h0e4
PVIDR _p3
h124
PVIDR _p4
h164
PVIDR _p5
h1a4
PVIDR _p6
h1e4
PVIDR _p7
h224
PVIDR _p8
h264
PVIDR _p9
h2a4
PVIDR _p10
h2e4
PVIDR _p11
h324
PVIDR _p12
31
13 12 11
16 15
Priority
Bit [0:11]
Port VLAN ID (PVID)
Bit [12]
Reserved
Bit [15:13] Priority
Bit [31:16] Reserved
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0
Port VLAN ID
MDS213
19.0
DC Electrical Characteristics
19.1
Absolute Maximum Ratings
Data Sheet
Package: 456 HBGA (Heatslug BGA)
Storage Temperature: -65C to +150C
Operating Temperature: 0C to +70C
Maximum Junction Temperature:125C
Supply Voltage VCC 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 5V Tolerant Input Pins
-0.5 V to (VCC + 3.3 V)
Caution: Stresses above those listed may cause permanent device failure. Functionality at or above these limits is
not implied. Exposure to the Absolute Maximum Ratings for extended periods may affect device reliability.
19.2
DC Electrical Characteristics
VCC = 3.0 V to 3.6 V (3.3v +/- 10%)TAMBIENT = 0 C to +70 C
VDD = 2.5V +10% - 5%
Recommended Operating Conditions
Symbol
Parameter Description
Min
Type
Max
Unit
fosc
Frequency of Operation
100
ICC
Supply Current - @ 100 MHz (VCC =3.3 V)
270
351
mA
780
1014
mA
IDD
Supply Current - @ 100 MHz (VDD =2.5 V)
VOH
Output High Voltage (CMOS)
VOL
Output Low Voltage (CMOS)
MHz
2.4
0.4
V
VIH-TTL
Input High Voltage (TTL 5V tolerant)
VCC + 2.0
V
VIL-TTL
Input Low Voltage (TTL 5V tolerant)
0.8
V
IIL
Input Leakage Current (all pins except those
with internal pull-up/pull-down resistors)
10
µA
IOL
Output Leakage Current
10
µA
CIN
Input Capacitance
5
pF
Output Capacitance
5
pF
I/O Capacitance
7
pF
COUT
CI/O
2.0
V
θja
Thermal resistance with 0 air flow
121
θja
Thermal resistance with 1 m/s air flow
11
C/W
θja
Thermal resistance with 2 m/s air flow
9.6
C/W
θjc
Thermal resistance between junction and case
3.3
C/W
Note 1:
When external heat sink is attached, θJA is reduced by about 8-12% in still air.
108
Zarlink Semiconductor Inc.
C/W
MDS213
20.0
AC Specifications
20.1
XPIPE Interface
X_DCLKI
X_DCLKO
X_FCO
Data Sheet
X_DCLKI
X17
X1-max
X1-min
X18
X_DI[31:0]
X19
X4-max
X4-min
X20
X_DENI
X21
X3-max
X3-min
X22
X_FCI
X_DENO
X2-max
X2-min
XPIPE INTERFACE - Input setup and hold timing
X_DO[31:0]
S_CLK
X15
XPIPE INTERFACE - Output valid delay timing
X16
X_DCLK
Figure 26 - XPIPE Interface - Output Valid Delay Timing
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Zarlink Semiconductor Inc.
MDS213
Symbol
Data Sheet
-100MHZ
Parameter
Min (ns)
Max (ns)
Note
X1
X_DCLKO output valid delay
1
5
CL = 30pf
X2
X_DO[31:0] output valid delay
1
5
CL = 30pf
X3
X_DENO output valid delay
1
5
CL = 30pf
X4
X_FCO output valid delay
1
5
CL = 30pf
X15
X_DCLKI input set-up time
3
Reference S-CLK
X16
X_DCLKI input hold time
0
Reference S-CLK
X17
X_DI[31:0] input set-up time
3
X18
X_DI[31:0] input hold time
0
X19
X_DENI input set-up time
3
X20
X_DENI input hold time
0
X21
X_FCI input set-up time
3
X22
X_FCI input hold time
0
Table 11 - AC Characteristics - XPipe Interface
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Zarlink Semiconductor Inc.
MDS213
20.2
Data Sheet
CPU BUS Interface
P_CLK
P_CLK
P19-max
P19-min
P1
P_D[31:0]
P2
P_RST#
P_RDY#
P23-max
P23-min
P3
P4
P_ADS#
P24-max
P24-min
P5
P6
P_INT
P_RWC#
P7
CPU BUS INTERFACE - Output valid delay timing
P8
P_CSI#
P9
P20-max
P20-min
P10
P_A[10:1]
P_A[10:1]
P_RWC#
P11
P21-max
P21-min
P12
P_D[31:0]
CPU BUS INTERFACE - Input setup and hold timing
P22-max
P22-min
P15
P_ADS#
P16
P_REQC
P25-max
P25-min
P17
P_GNTC
P18
P_GNT1
P_REQ1
P26-max
P26-min
Figure 27 - AC Characteristics - CPU BUS Interface
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Zarlink Semiconductor Inc.
MDS213
Symbol
Data Sheet
-66MHZ
Parameter
Min (ns)
Max (ns)
Note
P_CLK
P1
P_RST# input setup time
6
P2
P_RST# input hold time
2
P3
P_ADS# input setup time
6
P4
P_ADS# input hold time
2
P5
P_RWC# input setup time
6
P6
P_RWC# input hold time
2
P7
P_CSI# input setup time
6
P8
P_CSI# input hold time
2
P9
P_A[10:1] input setup time
6
P10
P_A[10:1] input hold time
2
P11
P_D[31:0] input setup time
6
P12
P_D[31:0] input hold time
2
P15
P_REQC input setup time
6
P16
P_REQC input hold time
2
P17
P_REQI input setup time
6
P18
P_REQI input hold time
2
P19
P_D[31:0] output valid delay
2
12
CL = 65pf
P20
P_A[10:1] output valid delay
2
9
CL = 50pf
P21
P_RWC# output valid delay
2
9
CL = 50pf
P22
P_ADS# output valid delay
2
9
CL = 50pf
P23
P_RDY# output valid delay
2
9
CL = 50pf
P24
P_INT output valid delay
2
9
CL = 30pf
P25
P_GNTC output valid delay
2
9
CL = 20pf
P26
P_GNT1 output valid delay
2
9
CL = 20pf
Table 12 - AC Characteristics - CPU Bus Interface
112
Zarlink Semiconductor Inc.
MDS213
20.3
Data Sheet
Local SBRAM Memory Interface
L_CLK
LOCAL SBRAM MEMORY INTERFACE
L_CLK
L3-max
L3-min
L_D[63:0]
L1
L2
L4-max
L4-min
L_D[63:0]
L_A[20:3]
LOCAL MEMORY INTERFACE Input setup and hold timing
L6-max
L6-min
L_ADSC#
L7-max
L7-min
L_BW[7:0]#
L8-max
L8-min
L_WE[1:0]#
L9-max
L9-min
L_OE[1:0]#
LOCAL MEMORY INTERFACE Output valid delay timing
Figure 28 - Local Memory Interface - Input Setup and Output Valid Delay Timing
Symbol
-100MHZ
Parameter
Min (ns)
Max (ns)
L_CLK
Note
CL = 50pf
L1
L_D[63:0] input set-up time
3
L2
L_D[63:0] input hold time
L3
L_D[63:0] output valid delay
2
7
CL = 30pf
L4
L_A[20:3] output valid delay
2
7
CL = 50pf
L6
L_ADSC# output valid delay
2
7
CL = 50pf
L7
L_BW[7:0]# output valid delay
2
7
CL = 30pf
L8
L_WE[1:0]# output valid delay
2
7
CL = 30pf
L9
L_OE[1:0]# output valid delay
0
1
CL = 30pf
1.5
Table 13 - AC Characteristics - Local SBRAM Memory Interface
113
Zarlink Semiconductor Inc.
MDS213
Data Sheet
M_CLK
PM1
PM2
PM_DENI
PM3
PM4
PM_D[1:0]
PM5
Figure 29 - Port Mirroring Interface - Input Setup and Hold Timing
M_CLKI
PM6-max
PM6-min
PM_DENO
PM_DO[1:0]
PM7-max
PM7-min
Figure 30 - Port Mirroring Interface - Output Delay Timing
M_CLKI
M1
M2
M[11:0]_RXD[1:0]
M3
M4
M[11:0]_CRS_DV
M5
Figure 31 - Reduce Media Independent Interface - Input Setup and Hold Timing
M_CLKI
M6-max
M6-min
M[11:0]_TXEN
M[11:0]_TXD[1:0]
M7-max
M7-min
Figure 32 - Reduce Media Independent Interface - Output Delay Timing
114
Zarlink Semiconductor Inc.
MDS213
Symbol
Data Sheet
-50 MHZ
Parameter
Min (ns)
Note
Max (ns)
PM1
M_CLKI
Reference
Input Clock
PM2
PM_DENI Input Setup Time
1.5
PM3
PM_DENI Input Hold Time
2
PM4
PM_DI[1:0] Input Setup Time
1.5
PM5
PM_DI[1:0] Input Hold Time
2
PM6
PM_DENO Output Delay Time
2
11
CL = 30pf
PM7
PM_DO[1:0] Output Delay Time
2
11
CL = 30pf
Table 14 - AC Characteristics - Port Mirroring Interface
Symbol
-50 MHZ
Parameter
Min (ns)
Note
Max (ns)
M1
M_CLKI
Reference
Input Clock
M2
M[11:0]_RXD[1:0] Input Setup Time
1.5
M3
M[11:0]_RXD[1:0] Input Hold Time
2
M4
M[11:0]_CRS_DV Input Setup Time
2
M5
M[11:0]_CRS_DV Input Hold Time
1
M6
M[11:0]_TXEN Output Delay Time
2
11
CL = 30pf
M7
M[11:0]_TXD[1:0] Output Delay Time
2
11
CL = 30pf
Table 15 - AC Characteristics - Reduced Media Independent Interface
115
Zarlink Semiconductor Inc.
MDS213
M[12]_RXCLK
M[12]_RXD[7:0]
Data Sheet
M[12]_TXCLK
G1
G2
G11-max
G11-min
M[12]_TXD[7:0]
G3
G4
M[12]_RX_DV
G12-max
G12-min
M[12]_TX_EN
G5
G6
M[12]_RX_ER
G13-max
G13-min
M[12]_TX_ER
G7
G8
M[12]_CRS
Output Valid Delay Timing
G9
G10
M[12]_COL
Input Setup and Hold Timing
Symbol
-125 MHZ
Parameter
Min (ns)
Note
Max (ns)
M[12]_RXCLK
Input Reference
Clock
G1
M[12]_RXD[7:0] Input Setup Times
2
G2
M[12]_RXD[7:0] Input Hold Times
0
G3
M[12]_RX_DV Input Setup Times
2
G4
M[12]_RX_DV Input Hold Times
0
G5
M[12]_RX_ER Input Setup Times
2
G6
M[12]_RX_ER Input Hold Times
0
G7
M[12]_CRS Input Setup Times
2
G8
M[12]_CRS Input Hold Times
0
G9
M[12]_COL Input Setup Times
2
G10
M[12]_COL Input Hold Times
0
M[12]_TXCLK
Output
Reference Clock
G11
M[12]_TXD[7:0] Output Delay Times
1
5
CL = 20pf
G12
M[12]_TX_EN Output Delay Times
1
5
CL = 20pf
G13
M[12]_TX_ER Output Delay Times
1
5
CL = 20pf
Table 16 - AC Characteristics - Gigabit Media Independent Interface
116
Zarlink Semiconductor Inc.
MDS213
Data Sheet
GP_RXCLK0
/GP_RXCLK1
GP1
GP2
GP_RXD[9:0]
Figure 33 - Input Setup and Hold Timing
GP_TXCLK
GP3-max
GP3-min
GP_TXD[9:0]
Figure 34 - Output Valid Delay Timing
Symbol
-125 MHZ
Parameter
Min (ns)
GP_RXCLK0/
GP_RXCLK1
Input
Reference
Clock
GP1
GP_RXD[9:0] Input Setup Times
2
GP2
GP_RXD[9:0] Input Hold Times
0
GP_TXCLK
GP3
Note
Max (ns)
Output
Reference
Clock
GP_TXD[9:0] Output Delay Times
1
5
CL = 20pf
Table 17 - AC Characteristics - Physical Media Attachment Interface
LED_CLKO
LE1
LE2-max
LE2-min
LED_DO
LED_SYNCO
LE3-max
LE3-min
Figure 35 - LED Interface - Output Delay Timing
117
Zarlink Semiconductor Inc.
MDS213
Symbol
Data Sheet
Variable Freq.
Parameter
Min (ns)
Max (ns)
Note
LE1
LE_CLKO
Reference
Output Clock
LE2
LE-DO Output Valid Delay
-1
7
CL = 30pf
LE3
LE_SYNCO Output Valid Delay
-1
7
CL = 30pf
Table 18 - AC Characteristics - LED Interface
118
Zarlink Semiconductor Inc.
E1
DIMENSION
A
A1
A2
D
D1
E
E1
b
e
MIN
MAX
2.20
2.46
0.50
0.70
1.17 REF
35.20
34.80
30.00 REF
35.20
34.80
30.00 REF
0.60
0.90
1.27
456
Conforms to JEDEC MS - 034
E
e
D1
D
A2
A1
A
1. CONTROLLING DIMENSIONS ARE IN MM
2. DIMENSION "b" IS MEASURED AT THE MAXIMUM SOLDER BALL DIAMETER
3. PRIMARY DATUM -C- AND SEATING PLANE
ARE DEFINED BY THE SPHERICAL CROWNS OF THE SOLDER BALLS.
4. N IS THE NUMBER OF SOLDER BALLS
5. NOT TO SCALE.
6. SUBSTRATE THICKNESS IS 0.56 MM
Package Code
c Zarlink Semiconductor 2003 All rights reserved.
ISSUE
ACN
DATE
APPRD.
Previous package codes:
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