Low Latency E-Tile 40G Ethernet Intel® FPGA IP User Guide

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ID 683486
Date 7/12/2024
Public
Document Table of Contents
Document Table of Contents x
1. About the Low Latency E-Tile 40G Ethernet Intel® FPGA IP 2. Low Latency E-Tile 40G Ethernet IP Core Parameters 3. Getting Started 4. Functional Description 5. Reset 6. Interfaces and Signal Descriptions 7. Control, Status, and Statistics Register Descriptions 8. Debugging the Link 9. Ethernet Toolkit Overview 10. Low Latency E-Tile 40G Ethernet Intel® FPGA IP User Guide Archives 11. Comparison Between Low Latency E-Tile 40G Ethernet Core and Low Latency 40GbE IP Core 12. Document Revision History for Low Latency E-Tile 40G Ethernet Intel® FPGA IP User Guide
1. About the Low Latency E-Tile 40G Ethernet Intel® FPGA IP x
1.1. Release Information 1.2. Low Latency E-Tile 40G Ethernet Intel® FPGA IP Supported Features 1.3. Low Latency E-Tile 40G Ethernet Intel® FPGA IP Device Family and Speed Grade Support 1.4. Resource Utilization
1.3. Low Latency E-Tile 40G Ethernet Intel® FPGA IP Device Family and Speed Grade Support x
1.3.1. Device Family Support 1.3.2. Low Latency E-Tile 40G Ethernet Intel® FPGA IP Device Speed Grade Support
3. Getting Started x
3.1. Installing and Licensing Intel® FPGA IP Cores 3.2. Specifying the Low Latency E-Tile 40G Ethernet IP Core Parameters and Options 3.3. Simulating the IP Core 3.4. Generated File Structure 3.5. Integrating Your IP Core in Your Design 3.6. Low Latency E-Tile 40G Ethernet IP Core Testbench 3.7. Compiling the Full Design and Programming the FPGA
3.5. Integrating Your IP Core in Your Design x
3.5.1. Pin Assignments 3.5.2. Ethernet Adaptation Flow 3.5.3. Placement Settings for the Low Latency E-Tile 40G Ethernet Core
3.6. Low Latency E-Tile 40G Ethernet IP Core Testbench x
3.6.1. Understanding the Testbench Behavior
4. Functional Description x
4.1. Low Latency E-Tile 40G Ethernet Core Functional Description 4.2. User Interface to Ethernet Transmission
4.1. Low Latency E-Tile 40G Ethernet Core Functional Description x
4.1.1. Low Latency E-Tile 40G Ethernet Core TX MAC Datapath 4.1.2. Low Latency E-Tile 40G Ethernet Core RX MAC Datapath 4.1.3. Link Fault Signaling Interface 4.1.4. Flow Control
4.1.1. Low Latency E-Tile 40G Ethernet Core TX MAC Datapath x
4.1.1.1. Frame Padding 4.1.1.2. Preamble Insertion 4.1.1.3. Inter-Packet Gap Generation and Insertion 4.1.1.4. Frame Check Sequence (CRC-32) Insertion
4.1.2. Low Latency E-Tile 40G Ethernet Core RX MAC Datapath x
4.1.2.1. IP Core Preamble Processing 4.1.2.2. IP Core Strict SFD Checking 4.1.2.3. Length/Type Field Processing 4.1.2.4. RX CRC Checking and Dynamic Forwarding
4.1.2.3. Length/Type Field Processing x
4.1.2.3.1. Length Checking
4.1.4. Flow Control x
4.1.4.1. TX Pause/PFC Flow Control Transmission 4.1.4.2. XON/XOFF Pause Frames
4.2. User Interface to Ethernet Transmission x
4.2.1. Order of Transmission 4.2.2. Bit Order For TX and RX Datapaths
6. Interfaces and Signal Descriptions x
6.1. TX MAC Interface to User Logic 6.2. RX MAC Interface to User Logic 6.3. Transceivers Signals 6.4. Transceiver Reconfiguration Signals 6.5. Avalon® Memory-Mapped Management Interface 6.6. Miscellaneous Status and Debug Signals 6.7. Reset Signals 6.8. Clocks 6.9. Flow Control Interface
7. Control, Status, and Statistics Register Descriptions x
7.1. PHY Registers 7.2. TX MAC Registers 7.3. RX MAC Registers 7.4. Pause/PFC Flow Control Registers
9. Ethernet Toolkit Overview x
9.1. Features
1. About the Low Latency E-Tile 40G Ethernet Intel® FPGA IP
2. Low Latency E-Tile 40G Ethernet IP Core Parameters
3. Getting Started
4. Functional Description
5. Reset
6. Interfaces and Signal Descriptions
7. Control, Status, and Statistics Register Descriptions
8. Debugging the Link
9. Ethernet Toolkit Overview
10. Low Latency E-Tile 40G Ethernet Intel® FPGA IP User Guide Archives
11. Comparison Between Low Latency E-Tile 40G Ethernet Core and Low Latency 40GbE IP Core
12. Document Revision History for Low Latency E-Tile 40G Ethernet Intel® FPGA IP User Guide

5. Reset

Control and Status registers control three parallel soft resets. These soft resets are not self-clearing. Software clears them by writing to the appropriate register. In addition, the IP core has three hard reset signals.

Asserting the external hard reset csr_rst_n returns all Control and Status registers to their original values, except the statistics counters. An additional dedicated reset signal resets the transceiver reconfiguration interface.

Figure 10. Conceptual Overview of General IP Core Reset Logic The three hard resets are top-level ports. The three soft resets are internal signals which are outputs of the PHY_CONFIG register. Software writes the appropriate bit of the PHY_CONFIG to assert a soft reset.

The general reset signals reset the following functions:

  • soft_tx_rst, tx_rst_n: Resets the IP core in the TX direction. Resets the TX PCS and TX MAC. This reset leads to deassertion of the tx_lanes_stable output signal.
  • soft_rx_rst, rx_rst_n: Resets the IP core in the RX direction. Resets the RX PCS and RX MAC. This reset leads to deassertion of the rx_pcs_ready output signal.
  • sys_rst, csr_rst_n: Resets the IP core. Resets the TX and RX MACs, PCS, and transceivers.
    Note: csr_rst_n resets the Control and Status registers, except the statistics counters. sys_rst does not reset any Control and Status registers.
    This reset leads to deassertion of the tx_lanes_stable and rx_pcs_ready output signals.

In addition, the synchronous reconfig_reset signal resets the IP core transceiver reconfiguration interface, an Avalon® memory-mapped interface. Associated clock is the reconfig_clk, which clocks the transceiver reconfiguration interface.

The CSR register read/write needs to wait at least 2 clock cycles after csr_rst_n assertion.

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