F-Tile Serial Lite IV Intel® FPGA IP Design Example User Guide

ID 683287
Date 7/06/2024
Public
Document Table of Contents

3.9.3. RX DL Shim Wrapper

Figure 27. Data Flow

After the F-Tile Serial Lite IV Intel® FPGA IP is aligned/RX link is up, data will be ready to be passed to user logic or the RX DCFIFO/buffer as shown in the figure.. The data will be written to the RX DCFIFO/buffer. The RX buffer triggers the RBD delay on every detected SYSREF rising edge and at the end of the RBD_Delay, checks whether the DLCW word has been received on all the RX lanes and then only pass the data to the RX Proc logic and asserts the rx_in_sync signal. The RBD delay should manage the SL4 IP skew variation between lanes as well as any variation due to the transfer of real-time samples over different clock domains.

Since the FEC alignment marker insertion cycles (4 cycles), cadence cycles (1 cycle), and other scenarios (paired CWs, 2 cycles) can occur consecutively or concurrently, the worst case number of tx_ready de-assertion cycles is seven. Also, if taking into consideration the maximum of five parallel rx_core_clk cycles of the inter-lane skews scenario, the RBD value must be programmed to ensure that data is read from RX buffer when the buffer occupancy is ≥13, this is to ensure the continuity of data when the F-Tile Serial Lite IV Intel® FPGA IP TX would insert holes due to its protocol overhead in the worst case scenario mentioned previously.

Figure 28. RBD Delay Conceptual Diagram

The RBD value must be greater than the latency of TX+RX (including TX DL shim and RX DL shim) in the user_clk cycle, plus an additional ≥13 to prefill the RX DCFIFO.

For example, the latency of TX+RX = 172 user clock cycles, prefill value =13. So, the total delay value to be set is 185. The total latency of TX+RX (including TX DL shim and RX DL shim) will be a deterministic value of 185 user clock cycles. Users can set the RBD_COUNT parameter value to 8’d185.

Figure 29. RX DL Shim Wrapper Parameters
Note: Set the same DLCW parameter value as the DLCW parameter set in the tx_dl_wrapper module.
Table 18.  RX DL Shim Wrapper I/O Signals
Signal Name Direction Type Description
rx_user_clk Input Wire Input clock from user clock source.
rx_core_clkout Input Wire Input clock from F-Tile Serial Lite IV Intel® FPGA IP rx_core_clk.
rx_rst Output Wire Active high asynchronous reset. Asserts the reset when IP core rx_core_rst is asserted.
sysref Input Wire Periodic pulse signal from SYSREF Generator.
rxinsync Output Reg Indicates DLCW word has been received on all the lanes and the data has been passed to the RX Proc logic.
rx_data Input Wire [(N*2*64)-1:0] Avalon® streaming interface Data signal from F-Tile Serial Lite IV Intel® FPGA IP core.
rx_valid Input Wire Avalon® streaming interface Valid signal from F-Tile Serial Lite IV Intel® FPGA IP core.
rx_fifo_ready_empty Output Wire Output status signal to indicate the internal FIFO hits empty status.
rx_fifo_rd_pfull_out Output Wire [5:0] Output status signal to indicate the internal FIFO hits partial full status.
rx_data_out Output Wire [(N*2*64)-1:0] Avalon® streaming interface Data to user traffic checker.
rx_data_valid Output Wire Output Avalon® streaming interface Valid to user traffic checker.
Note: The rx_valid_out from the RX wrapper module will start to be asserted once the first DL sync pattern (DLCW) is received at the RX side and the valid signal will continue to stay HIGH afterwards to maintain the fix DL value obtained. It is not recommended to rely on the rx_valid_out signal to start performing data checking as the user traffic checker module might not expect to receive the DLCW data.