Debug IP Core Using FPGA Data Capture
This example shows how to debug an IP core you generate in HDL Coder™ using only FPGA Data Capture as well as both AXI Manager and FPGA Data Capture together.
Xilinx® Zynq® ZC702 evaluation kit. For information on setting up the ZC702 hardware, see Getting Started with Targeting Xilinx Zynq Platform.
HDL Coder Support Package for Xilinx Zynq Platform
HDL Verifier™ Support Package for Xilinx FPGA Boards
Xilinx Vivado™ Design Suite, with a supported version listed in the HDL Language Support and Supported Third-Party Tools and Hardware
(Optional) Embedded Coder® Support Package for Xilinx Zynq Platform
(Optional) DSP System Toolbox
Monitoring IP core internal signals while a design is running on real hardware is useful because you can debug and analyze the design. This example illustrates how to use the FPGA Data Capture to capture internal signals of the generated IP core in MATLAB®.
This example shows how to use FPGA Data Capture in blocking and nonblocking modes. For more information on capture modes, see CaptureMode (HDL Verifier Support Package for Xilinx FPGA Boards). Nonblocking mode allows simultaneous use of AXI Manager and FPGA Data Capture over a JTAG interface. Blocking mode suspends MATLAB execution, so you cannot use other applications when you use this mode. By contrast, nonblocking mode allows you to use AXI Manager to configure the IP core while FPGA Data Capture captures data from the hardware.
Open the model.
This example implements the
led_counter subsystem on the hardware. This subsystem models a counter that causes LEDs to blink on the hardware. Two input ports,
Blink_direction, are control ports that determine the LED blink frequency and direction, respectively. The output port
LED connects to the LEDs on the hardware. You can use the output port
Read_back to read data back to MATLAB.
led_counter subsystem, several internal signals are test points. HDL Coder routes those internal signals out of the DUT and into the IP core wrapper so that the signals can be connected to the FPGA Data Capture HDL IP.
Generate HDL IP Core
Start HDL Workflow Advisor from the model and run through the IP Core Generation workflow. For a step-by-step guide, see Getting Started with Targeting Xilinx Zynq Platform.
1. In step 1.1, set Target workflow to
IP Core Generation and Target platform to
Xilinx Zynq ZC702 evaluation kit. Click Run This Task.
2. In step 1.2, set Reference design to
Default system. Set Insert AXI Manager (HDL Verifier required) and FPGA Data Capture (HDL Verifier required) to
JTAG. Click Run This Task.
3. In step 1.3, select Enable HDL DUT output port generation for test points.
4. In step 1.3, set the interface of the blinkfrequency, blinkdirection, led_output, and count ports to
FPGA Data Capture. Click Run This Task.
5. Run through the remaining workflow steps to generate the HDL IP and program the target device.
Capture and Display Data from IP Core
Next, capture data from the Zynq board.
Locate the FPGA Data Capture launch script. For this example, the script is in your HDL code generation directory:
hdl_prj/ip_core/led_count_ip_v1_0/fpga_data_capture/launchDataCaptureApp.m. You can also locate this script in the code generation report.
launchDataCaptureApp script in MATLAB. Add the script directory to the MATLAB path or change the current working folder.
Capture Data in Blocking Mode
Execute the script to launch the FPGA Data Capture tool. By default, FPGA Data Capture works in blocking mode. To capture data from the FPGA without setting a trigger condition, click Capture Data.
Alternatively, you can capture data with a trigger condition. For example, set the trigger condition
led_counter == 0 and the trigger position 32. Then, click Capture Data again.
Capture Data in Nonblocking Mode
Execute the script to launch the FPGA Data Capture tool and create the
fpgadc_obj object in the workspace. Change the capture mode to nonblocking by executing the following command at the MATLAB command prompt.
fpgadc_obj.CaptureMode = 'nonblocking';
FPGA Data Capture in nonblocking mode allows simultaneous use of FPGA Data Capture and AXI Manager. For more information, see Simultaneous Use of FPGA Data Capture and AXI Manager (HDL Verifier Support Package for Xilinx FPGA Boards). Now set a trigger condition where
led_blink_direction == 1 and set a trigger position of 512. Then, click Capture Data.
FPGA Data Capture waits for the trigger condition. As FPGA Data Capture allows AXI Manager to perform read and write operations in nonblocking mode.
Next, in FPGA Data Capture, set tp_blinkdirection to
High. Then, create an AXI Manager object in MATLAB.
axi_manager_obj = aximanager('Xilinx');
FPGA Data Capture captures the data in the Logic Analyzer. The figure shows the change in the blink direction.