NXP LPC1768 ARM Cortex-M3 LPCXpresso Demo
Including Embedded Web Server and USB Examples
[Embedded Ethernet Examples]
NOTE: This demo was created with the Red Suite IDE. NXP have since
acquired Code Red's technology and now the demo can instead be used with NXP's
The demo presented on this page is pre-configured to run on the RDB1768 evaluation board from Code Red (Code Red have since been acquired by NXP).
The board was fitted with an LPC1768
Cortex-M3 microcontroller from NXP.
The demo uses:
A Red Probe debug interface is built onto the RDB1768 so no additional debug interface hardware is required.
- The FreeRTOS GCC ARM Cortex-M3 port.
- The Red Suite Eclipse based IDE from Code Red (now the LPCXpresso IDE from NXP as noted at the top of this page) - which includes the FreeRTOS state viewer plug-in as standard. An Eclipse 'managed make' project is used.
- Adam Dunkels open source uIP embedded TCP/IP stack to implement a web server with CGI scripting.
- Bertrik Sikkens open source LPCUSB USB stack to implement a CDC class echo server.
uIP and LPCUSB are licensed separately from FreeRTOS. Users must familiarise themselves with the uIP and
LPCUSB licenses respectively.
The FreeRTOS ARM Cortex-M3 port includes a full interrupt nesting model. Interrupt priorities must be set in accordance with the
instructions on the Customisation page for correct operation.
IMPORTANT! Notes on using the NXP ARM Cortex-M3 Web Server Demo
Please read all the following points before using this RTOS port.
See also the FAQ My application does not run, what could be wrong?
- Source Code Organisation
- The Demo Application
- RTOS Configuration and Usage Details
Source Code Organisation
The Red Suite project for the LPC1768 demo is located in the FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite directory. This is the
directory to select when importing the project into your Red Suite workspace.
The FreeRTOS zip file download contains the files for all the ports and demo application projects. It therefore contains many more
files than used by this demo. See the Source Code Organization section for a description
of the downloaded files and information on creating a new project.
The Demo Application
Creating the project directory structure
The easiest way to use an Eclipse managed make build is to locate the required build files (C source files, header files and linker scripts)
under the directory that contains the Eclipse project file. FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite/CreateProjectDirectoryStructure.bat
is a batch file that will copy the required files from their normal locations within the FreeRTOS directory structure to sub directories under
the Eclipse project directory. The batch file must be executed prior to attempting a build.
Execute CreateProjectDirectoryStructure.bat from either a command prompt or Windows explorer. It cannot be executed successfully from within
the Eclipse environment itself.
Importing the project into a Red Suite workspace
- Start Red Suite. As it starts up you will be prompted for a workspace location. You can use your existing workspace or create a new one in a
- Within the Red Suite IDE, select 'Import...' from the 'File' menu.
- A dialog box will appear. Select 'Existing Projects Into Workspace', then click 'Next'.
- Browse to and select the FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite directory to complete the import process. Take care that the
'Copy projects into workspace' check box is NOT checked during this last step.
Importing the FreeRTOS project into the Red Suite workspace
Web server configuration
Connect the RDB1768 development board to a computer running a web browser either directly using a point to point (crossover)
cable, or via a Ethernet switch using a standard Ethernet cable.
The IP address used by the demo is set by the constants configIP_ADDR0 to
configIP_ADDR3 within the file FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite/src/FreeRTOSConfig.h. The MAC address and net mask are configured
within the same header file.
The IP addresses used by the web browser computer and the RDB1768 development board must be compatible.
This can be ensured by making the first three octets of both IP addresses identical.
For example, if the web browser computer uses IP address
192.168.100.1, then the development board can be given any address in the range 192.168.100.2 to 192.168.100.254 (barring
any addresses already present on the network).
Building and executing the demo application
Connect the RDB1768 to the host computer using the Debug USB port. This both powers the target and provides a debug interface.
To build the project, simply select 'Build All' from the 'Project' menu. The application should build with no errors
or warnings (assuming the #error statement has been removed).
A launch configuration needs to be created before a debug session can be started. This only needs to be done once, after
it has been created debug sessions can be started simply by clicking the 'Debug' speed button. To create a launch configuration
first select 'Open Debug Dialog...' from the 'Run' menu.
In the dialog box that opens, double click where it says 'C/C++ MCU Application' to create a new configuration. The configuration
parameters will be set automatically.
Finally click 'Debug' to program the MCU flash memory and start a debug session.
- Open main.c and search for a line that starts "#error". Delete the line (it provides instructions on setting up the directory
structure for those using the project without first reading these instructions).
Setting up the launch configuration
The demo application creates 36 tasks prior to starting the RTOS scheduler. These tasks consist
predominantly of the standard demo application tasks (see the demo application
section for details of the individual tasks). Their only purpose is to test the RTOS kernel port and provide
a demonstration of how to use the various API functions.
The following tasks and tests are created in addition to the standard demo tasks:
- Check function - called from the tick hook
This only executes every five seconds. Its main function is to check that all the
standard demo tasks are still operational. The check function maintains a status string that
can be viewed on the "Task Stats" page served by the uIP TCP/IP web server.
- uIP task
This is the task that handles the uIP stack. All TCP/IP processing is performed in this task.
- USB task
This is the task that handles the USB stack. The USB device will enumerate as a CDC device. The USB task simply echoes received characters with
an offset which by default is one. Therefore if 'A' is received 'B' will be echoed back. If 'x' is received 'y' will be echoed back, etc.
When executing correctly the demo application will behave as follows:
Served Web Pages
The top of each served page includes a menu containing a link to every other page.
The served RTOS stats page showing status information on each task in the system.
The served run time stats page showing the processor utilisation of each task.
The served IO page
The IO page provides a simple interface that permits data to be sent to an LED. The check box permits the state of
the user LED to be both set and queried.
Changes are sent to the target hardware by clicking the "Update IO" button.
The TCP Stats and Connections pages display run time networking information.
RTOS port specific configuration
Configuration items specific to these demos are contained in FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite/src/FreeRTOSConfig.h. The
constants defined in this file can be edited to suit your application. In particular -
Attention please!: Remember that ARM Cortex-M3 cores use numerically low priority numbers to represent HIGH
priority interrupts, which can seem counter-intuitive and is easy to forget! If you wish to assign an interrupt a low priority do NOT assign it a
priority of 0 (or other low numeric value) as this can result in the interrupt actually having the highest priority in the system - and therefore potentially make your system crash if this
priority is above configMAX_SYSCALL_INTERRUPT_PRIORITY.
This sets the frequency of the RTOS tick. The supplied value of 1000Hz is useful for
testing the RTOS kernel functionality but is faster than most applications require. Lowering this value will improve efficiency.
- configKERNEL_INTERRUPT_PRIORITY and configMAX_SYSCALL_INTERRUPT_PRIORITY
See the RTOS kernel configuration documentation for full information on these configuration constants.
The lowest priority on a ARM Cortex-M3 core is in fact 255 - however different ARM Cortex-M3 vendors implement a different number of priority bits and supply library
functions that expect priorities to be specified in different ways. Use the supplied examples as a reference.
Each port #defines 'BaseType_t' to equal the most efficient data type for that processor. This port defines
BaseType_t to be of type long.
Note that vPortEndScheduler() has not been implemented.
Interrupt service routines
In the demo application the vector table remains in flash.
Unlike most ports, interrupt service routines that cause a context switch have no special requirements and can be written as per the compiler documentation.
The macro portEND_SWITCHING_ISR() can be used to request a context switch from within an ISR. An example interrupt service routine called
vEMAC_ISR() is provided in FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite/src/webserver/emac.c. This should be used as a reference example.
Note that portEND_SWITCHING_ISR() will leave interrupts enabled.
Switching between the pre-emptive and co-operative RTOS kernels
Set the definition configUSE_PREEMPTION within FreeRTOS/Demo/CORTEX_LPC1768_GCC_RedSuite/src/FreeRTOSConfig.h to 1 to use pre-emption or 0
to use co-operative.
As with all the ports, it is essential that the correct compiler options are used. The best way to ensure this is to base your
application on the provided demo application files.
Source/Portable/MemMang/heap_2.c is included in the ARM Cortex-M3 demo application project to provide the memory
allocation required by the RTOS kernel.
Please refer to the Memory Management section of the API documentation for
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