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1. About the F-Tile Triple Speed Ethernet Intel FPGA IP User Guide
2. About This IP
3. Getting Started
4. Parameter Settings
5. Functional Description
6. Configuration Register Space
7. Interface Signals
8. Design Considerations
9. Timing Constraints
10. Software Programming Interface
11. F-Tile Triple-Speed Ethernet Intel® FPGA IP User Guide Archives
12. Document Revision History for the F-tile Triple-Speed Ethernet Intel® FPGA IP User Guide
A. Ethernet Frame Format
B. Simulation Parameters
5.1.1. MAC Architecture
5.1.2. MAC Interfaces
5.1.3. MAC Transmit Datapath
5.1.4. MAC Receive Datapath
5.1.5. MAC Transmit and Receive Latencies
5.1.6. FIFO Buffer Thresholds
5.1.7. Congestion and Flow Control
5.1.8. Magic Packets
5.1.9. MAC Local Loopback
5.1.10. MAC Reset
5.1.11. PHY Management (MDIO)
5.1.12. Connecting MAC to External PHYs
6.1.1. Base Configuration Registers (Dword Offset 0x00 – 0x17)
6.1.2. Statistics Counters (Dword Offset 0x18 – 0x38)
6.1.3. Transmit and Receive Command Registers (Dword Offset 0x3A – 0x3B)
6.1.4. Supplementary Address (Dword Offset 0xC0 – 0xC7)
6.1.5. IEEE 1588v2 Feature (Dword Offset 0xD0 – 0xD6)
6.1.6. Deterministic Latency (Dword Offset 0xE1– 0xE3)
6.1.7. IEEE 1588v2 Feature PMA Delay
7.1.1. 10/100/1000 Ethernet MAC Signals
7.1.2. 10/100/1000 Multiport Ethernet MAC Signals
7.1.3. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII PCS Signals
7.1.4. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII 2XTBI PCS and Embedded PMA Signals (F-Tile)
7.1.5. 10/100/1000 Ethernet MAC Without Internal FIFO Buffers with 1000BASE-X/SGMII 2XTBI PCS Signals
7.1.6. 10/100/1000 Ethernet MAC Without Internal FIFO Buffers with IEEE 1588v2 , 1000BASE-X/SGMII 2XTBI PCS, and Embedded Serial PMA Signals
7.1.7. 10/100/1000 Multiport Ethernet MAC with 1000BASE-X/SGMII PCS Signals
7.1.8. 10/100/1000 Ethernet MAC with 1000BASE-X/SGMII PCS and Embedded PMA Signals
7.1.9. 10/100/1000 Multiport Ethernet MAC with 1000BASE-X/SGMII PCS and Embedded PMA Signals
7.1.10. 1000BASE-X/SGMII PCS Signals
7.1.11. 1000BASE-X/SGMII 2XTBI PCS Signals
7.1.12. 1000BASE-X/SGMII PCS and PMA Signals
7.1.1.1. Clock and Reset Signals
7.1.1.2. Clock Enabler Signals
7.1.1.3. MAC Control Interface Signals
7.1.1.4. MAC Status Signals
7.1.1.5. MAC Receive Interface Signals
7.1.1.6. MAC Transmit Interface Signals
7.1.1.7. Pause and Magic Packet Signals
7.1.1.8. MII/GMII/RGMII Signals
7.1.1.9. PHY Management Signals
7.1.1.10. ECC Status Signals
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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3.3. Specifying the IP Core Parameters and Options
Quickly configure Intel® FPGA IP cores in the Intel® Quartus® Prime parameter editor. Double-click any component in the IP Catalog to launch the parameter editor. The parameter editor allows you to define a custom variation of the IP core. The parameter editor generates the IP variation synthesis and optional simulation files, and adds the .ip file representing the variation to your project automatically.
Follow these steps to locate, instantiate, and customize an IP core in the parameter editor:
- Create or open an Intel® Quartus® Prime project (.qpf) to contain the instantiated IP variation.
- In the IP Catalog (Tools > IP Catalog), locate and double-click the name of the IP core to customize. To locate a specific component, type some or all the component’s name in the IP Catalog search box. The New IP Variation window appears.
- Specify a top-level name for your custom IP variation. Do not include spaces in IP variation names or paths. The parameter editor saves the IP variation settings in a file named <your_ip> .ip. Click OK. The parameter editor appears.
- Set the parameter values in the parameter editor and view the block diagram for the component. The Parameterization Messages tab at the bottom displays any errors in IP parameters:
- Optionally, select preset parameter values if provided for your IP core. Presets specify initial parameter values for specific applications.
- Specify parameters defining the IP core functionality, port configurations, and device-specific features.
- Specify options for processing the IP core files in other EDA tools.
Note: Refer to your IP core user guide for information about specific IP core parameters. - Click Generate HDL. The Generation dialog box appears.
- Specify output file generation options, and then click Generate. The synthesis and simulation files generate according to your specifications.
- To generate a simulation testbench, click Generate > Generate Testbench System. Specify testbench generation options, and then click Generate.
- To generate an HDL instantiation template that you can copy and paste into your text editor, click Generate > Show Instantiation Template.
- Click Finish. Click Yes if prompted to add files representing the IP variation to your project.
- After generating and instantiating your IP variation, make appropriate pin assignments to connect ports.
Note: Some IP cores generate different HDL implementations according to the IP core parameters. The underlying RTL of these IP cores contains a unique hash code that prevents module name collisions between different variations of the IP core. This unique code remains consistent, given the same IP settings and software version during IP generation. This unique code can change if you edit the IP core's parameters or upgrade the IP core version. To avoid dependency on these unique codes in your simulation environment, refer to Generating a Combined Simulator Setup Script.