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1. About This IP
2. Getting Started with Altera IPs
3. Parameter Settings
4. Functional Description
5. Configuration Register Space
6. Interface Signals
7. Design Considerations
8. Timing Constraints
9. Testbench
10. Software Programming Interface
11. Triple-Speed Ethernet Intel® FPGA IP User Guide Archives
12. Document Revision History for the Triple-Speed Ethernet Intel® FPGA IP User Guide
A. Ethernet Frame Format
B. Simulation Parameters
4.1.1. MAC Architecture
4.1.2. MAC Interfaces
4.1.3. MAC Transmit Datapath
4.1.4. MAC Receive Datapath
4.1.5. MAC Transmit and Receive Latencies
4.1.6. FIFO Buffer Thresholds
4.1.7. Congestion and Flow Control
4.1.8. Magic Packets
4.1.9. MAC Local Loopback
4.1.10. MAC Error Correction Code (ECC)
4.1.11. MAC Reset
4.1.12. PHY Management (MDIO)
4.1.13. Connecting MAC to External PHYs
4.2.1. 1000BASE-X/SGMII PCS Architecture
4.2.2. Transmit Operation
4.2.3. Receive Operation
4.2.4. Transmit and Receive Latencies
4.2.5. GMII Converter
4.2.6. SGMII Converter
4.2.7. Auto-Negotiation
4.2.8. Ten-bit Interface
4.2.9. PHY Loopback
4.2.10. PHY Power-Down
4.2.11. 1000BASE-X/SGMII PCS Reset
5.1.1. Base Configuration Registers (Dword Offset 0x00 – 0x17)
5.1.2. Statistics Counters (Dword Offset 0x18 – 0x38)
5.1.3. Transmit and Receive Command Registers (Dword Offset 0x3A – 0x3B)
5.1.4. Supplementary Address (Dword Offset 0xC0 – 0xC7)
5.1.5. IEEE 1588v2 Feature (Dword Offset 0xD0 – 0xD6)
5.1.6. Deterministic Latency (Dword Offset 0xE1– 0xE3)
5.1.7. IEEE 1588v2 Feature PMA Delay
6.1.1. 10/100/1000 Ethernet MAC Signals
6.1.2. 10/100/1000 Multiport Ethernet MAC Signals
6.1.3. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII PCS Signals
6.1.4. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII 2XTBI PCS and Embedded PMA Signals (E-Tile)
6.1.5. 10/100/1000 Ethernet MAC Without Internal FIFO Buffers with 1000BASE-X/SGMII 2XTBI PCS Signals
6.1.6. 10/100/1000 Ethernet MAC Without Internal FIFO Buffers with IEEE 1588v2 and 1000BASE-X/SGMII 2XTBI PCS Signals
6.1.7. 10/100/1000 Ethernet MAC Without Internal FIFO Buffers with IEEE 1588v2, 1000BASE-X/SGMII 2XTBI PCS, SGMII Bridge, and Deterministic Latency Signals
6.1.8. 10/100/1000 Multiport Ethernet MAC with 1000BASE-X/SGMII PCS Signals
6.1.9. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII TBI (LVDS I/O only) PCS Signals
6.1.10. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII PCS and Embedded PMA Signals
6.1.11. 10/100/1000 Multiport Ethernet MAC with 1000BASE-X/SGMII PCS and Embedded PMA Signals
6.1.12. 1000BASE-X/SGMII PCS Signals
6.1.13. 1000BASE-X/SGMII 2XTBI PCS Signals
6.1.14. 1000BASE-X/SGMII PCS and PMA Signals
6.1.1.1. Clock and Reset Signals
6.1.1.2. Clock Enabler Signals
6.1.1.3. MAC Control Interface Signals
6.1.1.4. MAC Status Signals
6.1.1.5. MAC Receive Interface Signals
6.1.1.6. MAC Transmit Interface Signals
6.1.1.7. Pause and Magic Packet Signals
6.1.1.8. MII/GMII/RGMII Signals
6.1.1.9. PHY Management Signals
6.1.1.10. ECC Status Signals
6.1.11.1. IEEE 1588v2 RX Timestamp Signals
6.1.11.2. IEEE 1588v2 TX Timestamp Signals
6.1.11.3. IEEE 1588v2 TX Timestamp Request Signals
6.1.11.4. IEEE 1588v2 TX Insert Control Timestamp Signals
6.1.11.5. IEEE 1588v2 Time-of-Day (TOD) Clock Interface Signals
6.1.11.6. IEEE 1588v2 PCS Phase Measurement Clock Signal
6.1.11.7. IEEE 1588v2 PHY Path Delay Interface Signals
7.1. Optimizing Clock Resources in Multiport MAC with PCS and Embedded PMA
7.2. Sharing PLLs in Devices with LVDS Soft-CDR I/O
7.3. Sharing PLLs in Devices with GIGE PHY
7.4. Sharing Transceiver Quads
7.5. Migrating From Old to New User Interface For Existing Designs
7.6. Clocking Scheme of MAC with 2XTBI PCS and Embedded PMA
10.6.1. alt_tse_mac_get_common_speed()
10.6.2. alt_tse_mac_set_common_speed()
10.6.3. alt_tse_phy_add_profile()
10.6.4. alt_tse_system_add_sys()
10.6.5. triple_speed_ethernet_init()
10.6.6. tse_mac_close()
10.6.7. tse_mac_raw_send()
10.6.8. tse_mac_setGMII mode()
10.6.9. tse_mac_setMIImode()
10.6.10. tse_mac_SwReset()
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A.2. VLAN and Stacked VLAN Frame Format
The extension of a basic MAC frame is a virtual local area network (VLAN) tagged frame, which contains an additional 4-byte field for the VLAN tag and information between the source address and length/type fields. VLAN tagging is defined by the IEEE Standard 802.1Q. VLAN tagging can identify and separate many groups' network traffic from each other in enterprise and metro networks. Each VLAN group can consist of many users with varied MAC address in different geographical locations of a network. VLAN tagging increases and scales the network performance and add privacy and safety to various groups and customers' network traffic.
VLAN tagged frames have a maximum length of 1522 bytes, excluding the preamble and the SFD fields.
Figure 90. VLAN Tagged MAC Frame Format
In metro Ethernet applications, which require more scalability and security due to the sharing of an Ethernet link by many service providers, MAC frames can be tagged with two consecutive VLAN tags (stacked VLAN). Stacked VLAN frames contain an additional 8-byte field between the source address and client length/type fields, as illustrated.
Figure 91. Stacked VLAN Tagged MAC Frame Format