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This directory contains e2studio projects targeted at the Renesas RA 32-bit MCUs. The example projects include a wolfSSL TLS client. They also include benchmark and cryptography tests for the wolfCrypt library.
The wolfssl project contains both the wolfSSL and wolfCrypt libraries.
It is built as a Renesas RA C Library Project
and contains the Renesas RA
configuration. The wolfssl project uses Secure Cryptography Engine on RA6 Protected Mode
as hardware acceleration for cypto and TLS operation.
The other projects (benchmark, client, and test) are built as a
Renesas RA C Project Using RA Library
, where the RA library is the wolfssl project.
The wolfssl Project Summary is listed below and is relevant for every project.
Item | Name/Version |
---|---|
Board | EK-RA6M4 |
Device | R7FA6M4AF3CFB |
Toolchain | GCC ARM Embedded |
FSP Version | 5.4.0 |
Components | Version |
---|---|
Board Support Package Common Files | v5.4.0 |
Secure Cryptography Engine on RA6 Protected Mode | v5.4.0 |
I/O Port | v5.4.0 |
Arm CMSIS Version 5 - Core (M) | v6.1.0+fsp.5.4.0 |
RA6M4-EK Board Support Files | v5.4.0 |
Board support package for R7FA6M4AF3CFB | v5.4.0 |
Board support package for RA6M4 - Events | v5.4.0 |
Board support package for RA6M4 | v5.4.0 |
Board support package for RA6M4 - FSP Data | v5.4.0 |
FreeRTOS | v10.6.1+fsp.5.4.0 |
FreeRTOS - Memory Management - Heap 4 | v10.6.1+fsp.5.4.0 |
r_ether to FreeRTOS+TCP Wrapper | v5.4.0 |
Ethernet | v5.4.0 |
Ethernet PHY | v5.4.0 |
FreeRTOS+TCP | v4.0.0+fsp.5.4.0 |
FreeRTOS - Buffer Allocation 2 | v4.0.0+fsp.5.4.0 |
FreeRTOS Port | v5.4.0 |
1.) Import projects from [File]->[Open projects from File System]
2.) Create a dummy_library
Static Library.
RA C/C++ Project
.EK-RA6M4
from Drop-down list.Static Library
.FreeRTOS minimal - Static Allocation
. Click Finish.BSP
tab and increase Heap Size under RA Common
on Properties page, e.g. 0x1000Stacks
tabSCE Protected Mode
stack from New Stack
-> Security
Property | Value |
---|---|
Thread Symbol | sce_tst_thread |
Thread Name | sce_tst_thread |
Thread Stack size | increase depending on your environment e.g. 0xA000 |
Thread MemoryAllocation | Dynamic |
Common General Use Mutexes | Enabled |
Common General Enable Backward Compatibility | Enabled |
Common Memory Allocation Support Dynamic Allocation | Enabled |
Common Memory Allocation Total Heap Size | increase depending on your environment e.g. 0x20000, e.g. 0x30000 when using multi thread example |
Heap 4
stack to sce_tst_thread from New Stack
-> RTOS
-> FreeRTOS Heap 4
FreeRTOS + TCP
stack to sce_tst_thread from New Stack
-> Networking
-> FreeRTOS+TCP
and set propertiesProperty | Value |
---|---|
Network Events call vApplicationIPNetworkEventHook | Disable |
Use DHCP | Disable |
dummy_library
FSP configurationdummy_library
to wolfSSL_RA6M4
Generate Project Content
on Smart Configurator3.) Build the wolfSSL project
4.) Create a 'dummy_application' Renesas RA C Project Using RA Library.
RA C/C++ Project
.EK-RA6M4
from Drop-down list.Executable Using an RA Static Library
.dummy_application
as the project name. Click Next.RA library project
, select wolfSSL_RA6M4
.Copy the following folder and file at dummy_application
to test_RA6M4
\
script/\
src/sce_tst_thread_entry.c
Add sce_test()
call under /* TODO: add your own code here */ line at sce_tst_thread_entry.c
...
/* TODO: add your own code here */
sce_test();
...
5.) Prepare SEGGER_RTT to logging
J-Link Software and Documentation Pack
Copy sample program files below from Installed SEGGER
folder, e.g C:\Program Files\SEGGER\JLink\Samples\RTT
, to /path/to/wolfssl/IDE/Reenesas/e2studio/RA6M4/test/src/SEGGER_RTT
SEGGER_RTT.c\ SEGGER_RTT.h\ SEGGER_RTT_Conf.h\ SEGGER_RTT_printf.c
To connect RTT block, you can configure RTT viewer configuration based on where RTT block is in map file\ e.g.\ [test_RA6M4.map]
COMMON 0x200232a8 0xa8 ./src/SEGGER_RTT/SEGGER_RTT.o\
````
you can specify "RTT control block" to 0x200232a8 by Address\
OR\
you can specify "RTT control block" to 0x20020000 0x10000 by Search Range
## Run Client
1.) Enable TLS_CLIENT definition in wolfssl_demo.h of test_RA6M4 project
2.) Client IP address and Server IP address
+ Client IP address can be changed by the following line in wolf_client.c.
static const byte ucIPAddress[4] = { 192, 168, 11, 241 };
+ Client IP address can be changed by the following line in wolf_client.c.
#define SERVER_IP "192.168.11.40"
3.) Build test_RA6M4 project
4.) Prepare peer wolfssl server
+ On Linux
$ autogen.sh $ ./configure --enable-extended-master=no CFLAGS="-DWOLFSSL_STATIC_RSA -DHAVE_AES_CBC"
Run peer wolfSSL server
RSA sign and verify use, launch server with the following option
$./examples/server/server -b -d -i
ECDSA sign and verify use, launch server with the following option
$./examples/server/server -b -d -i -c ./certs/server-ecc.pem -k ./certs/ecc-key.pem
5.) Run the example Client
You will see the following message on J-LinK RTT Viewer when using RSA sign and verify.
Start Client Example, Connecting to 192.168.11.xx
[wolfSSL_TLS_client_do(00)][00] Start to connect to the server. [wolfSSL_TLS_client_do(00)][00] Cipher : NULL [wolfSSL_TLS_client_do(00)][00] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(01)][01] Start to connect to the server. [wolfSSL_TLS_client_do(01)][01] Cipher : ECDHE-RSA-AES128-GCM-SHA256 [wolfSSL_TLS_client_do(01)][01] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(02)][02] Start to connect to the server. [wolfSSL_TLS_client_do(02)][02] Cipher : ECDHE-RSA-AES256-SHA [wolfSSL_TLS_client_do(02)][02] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(03)][03] Start to connect to the server. [wolfSSL_TLS_client_do(03)][03] Cipher : ECDHE-RSA-AES128-SHA256 [wolfSSL_TLS_client_do(03)][03] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(04)][04] Start to connect to the server. [wolfSSL_TLS_client_do(04)][04] Cipher : AES128-SHA256 [wolfSSL_TLS_client_do(04)][04] Received: I hear you fa shizzle!
End of Client Example
You will see the following message on J-LinK RTT Viewer when using ECDSA sign and verify.
Start Client Example, Connecting to 192.168.11.xx
[wolfSSL_TLS_client_do(00)][00] Start to connect to the server. [wolfSSL_TLS_client_do(00)][00] Cipher : NULL [wolfSSL_TLS_client_do(00)][00] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(01)][01] Start to connect to the server. [wolfSSL_TLS_client_do(01)][01] Cipher : ECDHE-ECDSA-AES128-GCM-SHA256 [wolfSSL_TLS_client_do(01)][01] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(02)][02] Start to connect to the server. [wolfSSL_TLS_client_do(02)][02] Cipher : ECDHE-ECDSA-AES256-SHA [wolfSSL_TLS_client_do(02)][02] Received: I hear you fa shizzle!
[wolfSSL_TLS_client_do(03)][03] Start to connect to the server. [wolfSSL_TLS_client_do(03)][03] Cipher : ECDHE-ECDSA-AES128-SHA256 [wolfSSL_TLS_client_do(03)][03] Received: I hear you fa shizzle!
End of Client Exampl
**Note**\
To run "RSA verify" client, enable "#define USE_CERT_BUFFERS_2048" in wolfssl_demo.h\
To run "ECDSA verify" client, enable "#define USE_CERT_BUFFERS_256" in wolfssl_demo.h
### Run Multi Client Session example
1.) Enable TLS_CLIENT and TLS_MULTITHREAD_TEST definition in wolfssl_demo.h of test_RA6M4 project
2.) Follow [Run Client](#run-client) instruction
3.) Prepare peer wolfssl server
RSA sign and verify use, launch server with the following option
$./examples/server/server -b -d -i -p 11111
Open another terminal and launch another server example $./examples/server/server -b -d -i -p 11112
ECDSA sign and verify use, launch server with the following option
$./examples/server/server -b -d -c -i ./certs/server-ecc.pem -k ./certs/ecc-key.pem -p 11111
Open another terminal and launch another server example $./examples/server/server -b -d -c -i ./certs/server-ecc.pem -k ./certs/ecc-key.pem -p 11112
4.) Run Multi Client Session Example
You will see similar following message on J-LinK RTT Viewer when using ECDSA sign and verify.
Start Client Example, Connecting to 192.168.11.xx
clt_thd_taskA connecting to 11111 port clt_thd_taskB connecting to 11112 port [clt_thd_taskA][00] Ready to connect. [clt_thd_taskA][00] Start to connect to the server. [clt_thd_taskA][00] Cipher : ECDHE-RSA-AES128-GCM-SHA256 [clt_thd_taskB][00] Ready to connect. [clt_thd_taskB][00] Start to connect to the server. [clt_thd_taskB][00] Cipher : ECDHE-RSA-AES128-SHA256 [clt_thd_taskB][00] Received: I hear you fa shizzle!
[clt_thd_taskA][00] Received: I hear you fa shizzle!
clt_thd_taskA connecting to 11111 port clt_thd_taskB connecting to 11112 port [clt_thd_taskA][00] Ready to connect. [clt_thd_taskA][00] Start to connect to the server. [clt_thd_taskA][00] Cipher : AES128-SHA256 [clt_thd_taskB][00] Ready to connect. [clt_thd_taskB][00] Start to connect to the server. [clt_thd_taskB][00] Cipher : AES256-SHA256 [clt_thd_taskA][00] Received: I hear you fa shizzle!
[clt_thd_taskB][00] Received: I hear you fa shizzle!
End of Client Example
You will see similar following message on J-LinK RTT Viewer when using ECDSA sign and verify.
Start Client Example, Connecting to 192.168.11.xx
clt_thd_taskA connecting to 11111 port clt_thd_taskB connecting to 11112 port [clt_thd_taskA][00] Ready to connect. [clt_thd_taskA][00] Start to connect to the server. [clt_thd_taskA][00] Cipher : ECDHE-ECDSA-AES128-GCM-SHA256 [clt_thd_taskB][00] Ready to connect. [clt_thd_taskB][00] Start to connect to the server. [clt_thd_taskB][00] Cipher : ECDHE-ECDSA-AES128-SHA256 [clt_thd_taskB][00] Received: I hear you fa shizzle!
[clt_thd_taskA][00] Received: I hear you fa shizzle!
End of Client Example
**Note**\
Multi Client session use case is only able to run threads that all use either SCE cipher suite or SW cipher suite.
The example program runs two threads that use SCE cipher suite.
## Run Crypt test and Benchmark
1.) Enable CRYPT_TEST and/or BENCHMARK definition in wolfssl_demo.h
2.) Enable SCEKEY_INSTALLED definition in user_settings.h if you have installed key for AES
In the example code for benchmark, it assumes that AES key is installed at DIRECT_KEY_ADDRESS which is 0x08000000U as follows:
#if defined(SCEKEY_INSTALLED)
/* aes 256 */
memcpy(guser_PKCbInfo.sce_wrapped_key_aes256.value,
(uint32_t *)DIRECT_KEY_ADDRESS, HW_SCE_AES256_KEY_INDEX_WORD_SIZE*4);
guser_PKCbInfo.sce_wrapped_key_aes256.type = SCE_KEY_INDEX_TYPE_AES256;
guser_PKCbInfo.aes256_installedkey_set = 1;
/* aes 128 */
guser_PKCbInfo.aes128_installedkey_set = 0;
#endif ```
To install key, please refer Installing and Updating Secure Keys.
You can update code above to handle AES128 key when you install its key.
3.) Run Benchmark and Crypto Test
For support inquiries and questions, please email support@wolfssl.com. Feel free to reach out to info@wolfssl.jp as well.