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CMakeLists.txt | ||
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README.md | ||
sdkconfig.defaults |
Ethernet iperf Example
(See the README.md file in the upper level 'examples' directory for more information about examples.)
Overview
This example demonstrates basic usage of iperf protocol to measure the throughout/bandwidth of Ethernet.
The cli environment in the example is based on the console component.
How to use example
Hardware Required
To run this example, it's recommended that you have an official ESP32 Ethernet development board - ESP32-Ethernet-Kit. This example should also work for 3rd party ESP32 board as long as it's integrated with a supported Ethernet PHY chip. Up until now, ESP-IDF supports up to four Ethernet PHY: LAN8720
, IP101
, DP83848
and RTL8201
, additional PHY drivers should be implemented by users themselves.
esp_eth
component not only supports ESP32 internal Ethernet MAC controller, but also can drive third-party Ethernet module which integrates MAC and PHY and provides SPI interface. This example also take the DM9051 as an example, illustrating how to install the Ethernet driver with only a little different configuration.
Other Preparation
- Install iperf tool on PC
- Debian/Ubuntu:
sudo apt-get install iperf
- macOS:
brew install iperf
(if using Homebrew) orsudo port install iperf
(if using MacPorts) - Windows(MSYS2): Downloads binaries from here
- Debian/Ubuntu:
Project configuration in menuconfig
Enter make menuconfig
if you are using GNU Make based build system or enter idf.py menuconfig
if you' are using CMake based build system.
-
In the
Example Configuration
menu:-
Enable storing history commands in flash under
Store command history in flash
. -
Choose the kind of Ethernet this example will run on under
Ethernet Type
. -
If
Internal EMAC
is selected:- Choose PHY device under
Ethernet PHY Device
, by default, the ESP32-Ethernet-Kit has anIP101
on board.
- Choose PHY device under
-
If
SPI Ethernet Module
is selected:- Set SPI specific configuration, including GPIO and clock speed.
-
-
In the
Component config > Ethernet
menu:-
If
Internal EMAC
is selected:-
Enable
Use ESP32 internal EMAC controller
, and then go into this menu. -
In the
PHY interface
, it's highly recommended that you chooseReduced Media Independent Interface (RMII)
which will cost fewer pins. -
In the
RMII clock mode
, you can choose the source of RMII clock (50MHz):Input RMII clock from external
orOutput RMII clock from internal
. -
Once
Output RMII clock from internal
is enabled, you also have to set the number of the GPIO used for outputting the RMII clock underRMII clock GPIO number
. In this case, you can set the GPIO number to 16 or 17. -
Once
Output RMII clock from GPIO0 (Experimental!)
is enabled, then you have no choice but GPIO0 to output the RMII clock. -
Set SMI MDC/MDIO GPIO number according to board schematic, by default these two GPIOs are set as below:
Default Example GPIO RMII Signal Notes GPIO23 MDC Output to PHY GPIO18 MDIO Bidirectional -
If you have connect a GPIO to the PHY chip's RST pin, then you need to enable
Use Reset Pin of PHY Chip
and set the GPIO number underPHY RST GPIO number
.
-
-
If
SPI Ethernet Module
is selected:- Set the GPIO number used by interrupt pin under
DM9051 Interrupt GPIO number
.
- Set the GPIO number used by interrupt pin under
-
Extra configuration in the code (Optional)
- By default Ethernet driver will assume the PHY address to
1
, but you can alway reconfigure this value aftereth_phy_config_t phy_config = ETH_PHY_DEFAULT_CONFIG();
. The actual PHY address should depend on the hardware you use, so make sure to consult the schematic and datasheet.
Note: DM9051 has a fixed PHY address 1
, which cannot be modified.
Build and Flash
Enter make -j4 flash monitor
if you are using GNU Make based build system or enter idf.py build flash monitor
if you' are using CMake based build system.
(To exit the serial monitor, type Ctrl-]
.)
See the Getting Started Guide for full steps to configure and use ESP-IDF to build projects.
Example Output
Test uplink bandwidth
- PC: run command:
iperf -u -s -i 3
to start iperf server in UDP mode, and report interval is 3 seconds. - ESP32: run command:
iperf -u -c PC_IP -i 3 -t 30
to start iperf client in UDP mode, and the test will last 30 seconds.
PC output
------------------------------------------------------------
Server listening on UDP port 5001
Receiving 1470 byte datagrams
UDP buffer size: 208 KByte (default)
------------------------------------------------------------
[ 3] local 192.168.2.160 port 5001 connected with 192.168.2.156 port 49154
[ ID] Interval Transfer Bandwidth Jitter Lost/Total Datagrams
[ 3] 0.0- 3.0 sec 26.1 MBytes 72.8 Mbits/sec 0.198 ms 1/18585 (0.0054%)
[ 3] 3.0- 6.0 sec 26.3 MBytes 73.7 Mbits/sec 0.192 ms 0/18792 (0%)
[ 3] 6.0- 9.0 sec 26.3 MBytes 73.5 Mbits/sec 0.189 ms 0/18741 (0%)
[ 3] 9.0-12.0 sec 26.2 MBytes 73.3 Mbits/sec 0.191 ms 43/18739 (0.23%)
[ 3] 12.0-15.0 sec 26.3 MBytes 73.5 Mbits/sec 0.194 ms 0/18739 (0%)
[ 3] 15.0-18.0 sec 26.3 MBytes 73.5 Mbits/sec 0.191 ms 0/18741 (0%)
[ 3] 18.0-21.0 sec 26.3 MBytes 73.5 Mbits/sec 0.187 ms 0/18752 (0%)
[ 3] 21.0-24.0 sec 26.3 MBytes 73.4 Mbits/sec 0.192 ms 0/18737 (0%)
[ 3] 24.0-27.0 sec 26.3 MBytes 73.5 Mbits/sec 0.188 ms 0/18739 (0%)
ESP32 output
mode=udp-client sip=192.168.2.156:5001, dip=192.168.2.160:5001, interval=3, time=30
Interval Bandwidth
0- 3 sec 72.92 Mbits/sec
3- 6 sec 73.76 Mbits/sec
6- 9 sec 73.56 Mbits/sec
9- 12 sec 73.56 Mbits/sec
12- 15 sec 73.56 Mbits/sec
15- 18 sec 73.56 Mbits/sec
18- 21 sec 73.61 Mbits/sec
21- 24 sec 73.55 Mbits/sec
24- 27 sec 73.56 Mbits/sec
27- 30 sec 73.56 Mbits/sec
0- 30 sec 73.52 Mbits/sec
Test downlink bandwidth
- PC: run command:
iperf -u -c ESP_IP -b 80M -t 30 -i 3
to start iperf client in UDP mode with estimated bandwidth 100M, and report interval is 3 seconds. - ESP32: run command:
iperf -u -s -t 30 -i 3
to start iperf server in UDP mode, and the test will last 30 seconds.
PC output
------------------------------------------------------------
Client connecting to 192.168.2.156, UDP port 5001
Sending 1470 byte datagrams
UDP buffer size: 208 KByte (default)
------------------------------------------------------------
[ 3] local 192.168.2.160 port 59581 connected with 192.168.2.156 port 5001
[ ID] Interval Transfer Bandwidth
[ 3] 0.0- 3.0 sec 28.6 MBytes 80.0 Mbits/sec
[ 3] 3.0- 6.0 sec 28.6 MBytes 80.0 Mbits/sec
[ 3] 6.0- 9.0 sec 28.6 MBytes 80.0 Mbits/sec
[ 3] 9.0-12.0 sec 28.6 MBytes 80.0 Mbits/sec
[ 3] 12.0-15.0 sec 28.4 MBytes 79.5 Mbits/sec
[ 3] 15.0-18.0 sec 28.6 MBytes 79.9 Mbits/sec
[ 3] 18.0-21.0 sec 28.6 MBytes 79.9 Mbits/sec
[ 3] 21.0-24.0 sec 28.6 MBytes 79.9 Mbits/sec
[ 3] 24.0-27.0 sec 28.6 MBytes 80.0 Mbits/sec
[ 3] 27.0-30.0 sec 28.5 MBytes 79.7 Mbits/sec
[ 3] 0.0-30.0 sec 286 MBytes 79.9 Mbits/sec
ESP32 output
mode=udp-server sip=192.168.2.156:5001, dip=0.0.0.0:5001, interval=3, time=30
Interval Bandwidth
I (2534456) iperf: want recv=16384
0- 3 sec 79.36 Mbits/sec
3- 6 sec 79.56 Mbits/sec
6- 9 sec 79.51 Mbits/sec
9- 12 sec 79.24 Mbits/sec
12- 15 sec 77.33 Mbits/sec
15- 18 sec 79.01 Mbits/sec
18- 21 sec 78.58 Mbits/sec
21- 24 sec 78.24 Mbits/sec
24- 27 sec 79.56 Mbits/sec
27- 30 sec 77.20 Mbits/sec
0- 30 sec 78.76 Mbits/sec
Suggestions of getting higher bandwidth
- Higher MCU working frequency will get higher bandwidth.
- Put frequency invoked function into IRAM via macro
IRAM_ATTR
in code. - Priority of iperf task may also have effect.
Troubleshooting
-
RMII Clock
- ESP32's MAC and the external PHY device need a common 50MHz reference clock (aka RMII clock). This clock can either be provided by an externally oscillator or generated from internal APLL. The signal integrity of RMII clock is strict, so it is highly recommended to add a 33Ω resistor in series to reduce possible ringing.
- ESP32 can generate a 50MHz clock using internal APLL. But if the APLL is already used for other purposes (e.g. I2S peripheral), then you have no choice but use an external RMII clock.
-
GPIO connections
- RMII PHY wiring is fixed and can not be changed through either IOMUX or GPIO Matrix. They're described as below:
GPIO RMII Signal ESP32 EMAC Function GPIO21 TX_EN EMAC_TX_EN GPIO19 TX0 EMAC_TXD0 GPIO22 TX1 EMAC_TXD1 GPIO25 RX0 EMAC_RXD0 GPIO26 RX1 EMAC_RXD1 GPIO27 CRS_DV EMAC_RX_DRV
(For any technical queries, please open an issue on GitHub. We will get back to you as soon as possible.)