644 lines
21 KiB
Plaintext
644 lines
21 KiB
Plaintext
README
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^^^^^^
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Contents
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^^^^^^^^
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o Overview
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- Description
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- Fake Interrupts
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- Timing Fidelity
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o Debugging
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o Issues
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- 64-bit Issues
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- Compiler differences
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- Stack Size Issues
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- Networking Issues
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- X11 Issues
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o BASIC
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o Configurations
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Overview
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^^^^^^^^
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Description
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-----------
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This README file describes the contents of the build configurations available
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for the NuttX "sim" target. The sim target is a NuttX port that runs as a
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user-space program under Linux or Cygwin. It is a very "low fidelity" embedded
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system simulation: This environment does not support any kind of asynchonous
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events -- there are nothing like interrupts in this context. Therefore, there
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can be no pre-empting events.
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Fake Interrupts
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---------------
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In order to get timed behavior, the system timer "interrupt handler" is called
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from the sim target's IDLE loop. The IDLE runs whenever there is no other task
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running. So, for example, if a task calls sleep(), then that task will suspend
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wanting for the time to elapse. If nothing else is available to run, then the
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IDLE loop runs and the timer increments, eventually re-awakening the sleeping task.
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Context switching is based on logic similar to setjmp() and longjmp().
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The sim target is used primarily as a development and test platform for new
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RTOS features. It is also of academic interest. But it has no real-world
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application that I know of.
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Timing Fidelity
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---------------
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NOTE: In order to facility fast testing, the sim target's IDLE loop, by default,
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calls the system "interrupt handler" as fast as possible. As a result, there
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really are no noticeable delays when a task sleeps. However, the task really does
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sleep -- but the time scale is wrong. If you want behavior that is closer to
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normal timing, then you can define CONFIG_SIM_WALLTIME=y in your configuration
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file. This configuration setting will cause the sim target's IDLE loop to delay
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on each call so that the system "timer interrupt" is called at a rate approximately
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correct for the system timer tick rate. With this definition in the configuration,
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sleep() behavior is more or less normal.
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Debugging
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^^^^^^^^^
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One of the best reasons to use the simulation is that is supports great, Linux-
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based debugging. Here are the steps that I following to use the Linux ddd
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graphical front-end to GDB:
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1. Modify the top-level configuration file. Enable debug symbols by defining
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the following.
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cd <NuttX-Directory>
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CONFIG_DEBUG_SYMBOLS=y
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2. Re-build:
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cd <NuttX-Directory>
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make clean
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make
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3. Then start the debugging:
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ddd nuttx &
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gdb> b user_start
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gdb> r
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NOTE: This above steps work fine on both Linux and Cygwin. On Cygwin, you
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will need to start the Cywin-X server before running ddd.
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Issues
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^^^^^^
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64-Bit Issues
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-------------
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As mentioned above, context switching is based on logic like setjmp() and
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longjmp(). This context switching is available for 32-bit and 64-bit
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targets. You must, however, set the correct target in the configuration
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before you build: HOST_X86_64 or HOST_X86 for 62- and 32-bit targets,
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respectively. On a 64-bit machine, you can also force the 32-bit build
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with CONFIG_SIM_M32=y.
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There are other 64-bit issues as well. For example, addresses are retained in
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32-bit unsigned integer types in a few places. On a 64-bit machine, the 32-bit
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address storage may correcupt 64-bit addressing. NOTE: This is really a bug --
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addresses should not be retained in uint32_t types but rather in uintptr_t types
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to avoid issues just like this.
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Compiler differences
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--------------------
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operator new:
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Problem: "'operator new' takes size_t ('...') as first parameter"
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Workaround: Add -fpermissive to the compilation flags
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Stack Size Issues
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-----------------
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When you run the NuttX simulation, it uses stacks allocated by NuttX from the
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NuttX heap. The memory management model is exactly the same in the simulation
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as it is real, target system. This is good because this produces a higher
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fidelity simulation.
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However, when the simulation calls into Linux/Cygwin libraries, it will still
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use these small simulation stacks. This happens, for example, when you call
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into the system to get and put characters to the console window or when you
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make x11 calls into the system. The programming model within those libraries
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will assume a Linux/Cygwin environment where the stack size grows dynamically
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and not the small, limited stacks of a deeply embedded system.
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As a consequence, those system libraries may allocate large data structures
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on the stack and overflow the small NuttX stacks. X11, in particular,
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requires large stacks. If you are using X11 in the simulation, make sure
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that you set aside a "lot" of stack for the X11 system calls (maybe 8 or 16Kb).
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The stack size for the thread that begins with user start is controlled
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by the configuration setting CONFIG_USERMAIN_STACKSIZE; you may need to
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increase this value to larger number to survive the X11 system calls.
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If you are running X11 applications as NSH add-on programs, then the stack
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size of the add-on program is controlled in another way. Here are the
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steps for increasing the stack size in that case:
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cd ../apps/builtin # Go to the builtin apps directory
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vi builtin_list.h # Edit this file and increase the stack size of the add-on
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rm .built *.o # This will force the builtin apps logic to rebuild
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Networking Issues
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-----------------
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I never did get networking to work on the sim target. It tries to use the tap device
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(/dev/net/tun) to emulate an Ethernet NIC, but I never got it correctly integrated
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with the NuttX networking (I probably should try using raw sockets instead).
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Update: Max Holtzberg reports to me that the tap device actually does work properly,
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but not in an NSH configuration because of stdio operations freeze the simulation.
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X11 Issues
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----------
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There is an X11-based framebuffer driver that you can use exercise the NuttX graphics
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subsystem on the simulator (see the sim/nx11 configuration below). This may require a
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lot of tinkering to get working, depending upon where your X11 installation stores
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libraries and header files and how it names libraries.
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For example, on UBuntu 9.09, I had to do the following to get a clean build:
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cd /usr/lib/
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sudo ln -s libXext.so.6.4.0 libXext.so
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(I also get a segmentation fault at the conclusion of the NX test -- that will need
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to get looked into as well).
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The X11 examples builds on Cygwin, but does not run. The last time I tried it,
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XOpenDisplay() aborted the program. UPDATE: This was caused by the small stack
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size and can be fixed by increasing the size of the NuttX stack that calls into
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X11. See the discussion "Stack Size Issues" above.
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BASIC
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^^^^^
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BASIC
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=====
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I have used the sim/nsh configuration to test Michael Haardt's BASIC interpreter
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that you can find at apps/interpreters/bas.
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Bas is an interpreter for the classic dialect of the programming language
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BASIC. It is pretty compatible to typical BASIC interpreters of the 1980s,
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unlike some other UNIX BASIC interpreters, that implement a different
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syntax, breaking compatibility to existing programs. Bas offers many ANSI
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BASIC statements for structured programming, such as procedures, local
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variables and various loop types. Further there are matrix operations,
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automatic LIST indentation and many statements and functions found in
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specific classic dialects. Line numbers are not required.
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There is also a test suite for the interpreter that can be found at
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apps/examples/bastest.
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Configuration
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-------------
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Below are the recommended configuration changes to use BAS with the
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stm32f4discovery/nsh configuration:
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Dependencies:
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CONFIG_LIBC_EXECFUNCS=y : exec*() functions are required
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CONFIG_LIBM=y : Some floating point library is required
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CONFIG_LIBC_FLOATINGPOINT=y : Floating point printing support is required
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CONFIG_LIBC_TMPDIR="/tmp" : Writable temporary files needed for some commands
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Enable the BASIC interpreter. Other default options should be okay:
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CONFIG_INTERPRETERS_BAS=y : Enables the interpreter
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CONFIG_INTERPREPTER_BAS_VT100=y
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The BASIC test suite can be included:
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CONFIG_FS_ROMFS=y : ROMFS support is needed
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CONFIG_EXAMPLES_BASTEST=y : Enables the BASIC test setup
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CONFIG_EXAMPLES_BASTEST_DEVMINOR=6
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CONFIG_EXAMPLES_BASTEST_DEVPATH="/dev/ram6"
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Usage
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-----
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This setup will initialize the BASIC test (optional): This will mount
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a ROMFS file system at /mnt/romfs that contains the BASIC test files:
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nsh> bastest
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Registering romdisk at /dev/ram6
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Mounting ROMFS filesystem at target=/mnt/romfs with source=/dev/ram6
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nsh>
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The interactive interpreter is started like:
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nsh> bas
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bas 2.4
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Copyright 1999-2014 Michael Haardt.
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This is free software with ABSOLUTELY NO WARRANTY.
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>
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Ctrl-D exits the interpreter.
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The test programs can be ran like this:
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nsh> bastest
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Registering romdisk at /dev/ram0
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Mounting ROMFS filesystem at target=/mnt/romfs with source=/dev/ram0
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nsh> bas /mnt/romfs/test01.bas
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1
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hello
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0.0002
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0.0000020
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0.0000002
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nsh>
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Or you can load a test into memory and execute it interactively:
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nsh> bas
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bas 2.4
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Copyright 1999-2014 Michael Haardt.
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This is free software with ABSOLUTELY NO WARRANTY.
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> load "/mnt/romfs/test01.bas"
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> run
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1
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hello
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0.0002
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0.0000020
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0.0000002
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>
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Configurations
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^^^^^^^^^^^^^^
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Common Configuration Information
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--------------------------------
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1. Each configuration is maintained in a sub-directory and can be selected
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as follow:
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cd <nuttx-directory>/tools
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./configure.sh sim/<subdir>
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cd -
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. ./setenv.sh
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If this is a Windows native build, then configure.bat should be used
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instead of configure.sh:
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configure.bat sim\<subdir>
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Where <subdir> is one of the following sub-directories.
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2. All configurations uses the mconf-based configuration tool. To
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change this configuration using that tool, you should:
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a. Build and install the kconfig mconf tool. See nuttx/README.txt
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and misc/tools/
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b. Execute 'make menuconfig' in nuttx/ in order to start the
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reconfiguration process.
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Configuration Sub-Directories
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-----------------------------
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configdata
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A unit test for the MTD configuration data driver.
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cxxtest
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The C++ standard libary test at apps/examples/cxxtest configuration. This
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test is used to verify the uClibc++ port to NuttX.
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NOTES
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-----
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1. Before you can use this example, you must first install the uClibc++
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C++ library. This is located outside of the NuttX source tree at
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misc/uClibc++ in GIT. See the README.txt file for instructions on
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how to install uClibc++
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2. At present (2012/11/02), exceptions are disabled in this example
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CONFIG_UCLIBCXX_EXCEPTIONS=n). It is probably not necessary to
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disable exceptions.
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3. Unfortunately, this example will not run now.
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The reason that the example will not run on the simulator has
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to do with when static constructors are enabled: In the simulator
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it will attempt to execute the static constructors before main()
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starts. BUT... NuttX is not initialized and this results in a crash.
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To really use this example, I will have to think of some way to
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postpone running C++ static initializers until NuttX has been
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initialized.
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mount
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Configures to use apps/examples/mount.
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mtdpart
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This is the apps/examples/mtdpart test using a MTD RAM driver to
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simulate the FLASH part.
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mtdrwb
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This is the apps/examples/mtdrwb test using a MTD RAM driver to
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simulate the FLASH part.
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nettest
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Configures to use apps/examples/nettest. This configuration
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enables networking using the network TAP device.
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NOTES:
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1. The NuttX network is not, however, functional on the Linux TAP
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device yet.
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UPDATE: The TAP device does apparently work according to a NuttX
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user (provided that it is not used with NSH: NSH waits on readline()
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for console input. When it calls readline(), the whole system blocks
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waiting from input from the host OS). My failure to get the TAP
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device working appears to have been a cockpit error.
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2. As of NuttX-5.18, when built on Windows, this test does not try
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to use the TAP device (which is not available on Cygwin anyway),
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but inside will try to use the Cygwin WPCAP library. Only the
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most preliminary testing has been performed with the Cygwin WPCAP
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library, however.
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NOTE that the IP address is hard-coded in arch/sim/src/up_wpcap.c.
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You will either need to edit your configuration files to use 10.0.0.1
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on the "target" (CONFIG_EXAMPLES_NETTEST_*) or edit up_wpcap.c to
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select the IP address that you want to use.
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nsh
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Configures to use the NuttShell at apps/examples/nsh.
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NOTES:
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1. This version has one builtin function: This configuration:
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apps/examples/hello.
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2. This configuration has BINFS enabled so that the builtin applications
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can be made visible in the file system. Because of that, the
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build in applications do not work as other examples.
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For example trying to execute the hello builtin application will
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fail:
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nsh> hello
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nsh: hello: command not found
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nsh>
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Unless you first mount the BINFS file system:
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nsh> mount -t binfs /bin
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nsh> ls /bin
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/bin:
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hello
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nsh> echo $PATH
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/bin
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nsh> hello
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Hello, World!!
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nsh>
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Notice that the executable 'hello' is found using the value in the PATH
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variable (which was preset to "/bin"). If the PATH variable were not set
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then you would have to use /bin/hello on the command line.
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nsh2
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This is another example that configures to use the NuttShell at apps/examples/nsh.
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Like nsh, this version uses NSH built-in functions: The nx, nxhello, and
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nxlines examples are included as built-in functions.
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NOTES:
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1. X11 Configuration
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This configuration uses an X11-based framebuffer driver. Of course, this
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configuration can only be used in environments that support X11! (And it
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may not even be usable in all of those environments without some "tweaking"
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See discussion below under the nx11 configuration).
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nx
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Configures to use apps/examples/nx.
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NOTES:
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1. Special Framebuffer Configuration
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Special simulated framebuffer configuration options:
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CONFIG_SIM_FBHEIGHT - Height of the framebuffer in pixels
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CONFIG_SIM_FBWIDTH - Width of the framebuffer in pixels.
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CONFIG_SIM_FBBPP - Pixel depth in bits
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2. No Display!
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This version has NO DISPLAY and is only useful for debugging NX
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internals in environments where X11 is not supported. There is
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and additonal configuration that may be added to include an X11-
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based simulated framebuffer driver:
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CONFIG_SIM_X11FB - Use X11 window for framebuffer
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See the "nx11" configuration below for more information.
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3. Multi- and Single-User Modes
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The default is the single-user NX implementation. To select
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the multi-user NX implementation:
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CONFG_NX_MULTIUSER=y
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CONFIG_DISABLE_MQUEUE=n
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nx11
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Configures to use apps/examples/nx. This configuration is similar
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to the nx configuration except that it adds support for an X11-
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based framebuffer driver. Of course, this configuration can only
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be used in environments that support X11! (And it may not even
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be usable in all of those environments without some "tweaking").
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1. Special Framebuffer Configuration
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This configuration uses the same special simulated framebuffer
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configuration options as the nx configuration:
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CONFIG_SIM_X11FB - Use X11 window for framebuffer
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CONFIG_SIM_FBHEIGHT - Height of the framebuffer in pixels
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CONFIG_SIM_FBWIDTH - Width of the framebuffer in pixels.
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CONFIG_SIM_FBBPP - Pixel depth in bits
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2. X11 Configuration
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But now, since CONFIG_SIM_X11FB is also selected the following
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definitions are needed
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CONFIG_SIM_FBBPP (must match the resolution of the display).
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CONFIG_FB_CMAP=y
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My system has 24-bit color, but packed into 32-bit words so
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the correct setting of CONFIG_SIM_FBBPP is 32.
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For whatever value of CONFIG_SIM_FBBPP is selected, the
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corresponding CONFIG_NX_DISABLE_*BPP setting must not be
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disabled.
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3. Touchscreen Support
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A X11 mouse-based touchscreen simulation can also be enabled
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by setting:
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CONFIG_INPUT=y
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CONFIG_SIM_TOUCHSCREEN=y
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Then you must also have some application logic that will call
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arch_tcinitialize(0) to register the touchscreen driver. See
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also configuration "touchscreen"
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NOTES:
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a. If you do not have the call to sim_tcinitialize(0), the build
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will mysteriously fail claiming that is can't find up_tcenter()
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and up_tcleave(). That is a consequence of the crazy way that
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the simulation is built and can only be eliminated by calling
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up_simtouchscreen(0) from your application.
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b. You must first up_fbinitialize() before calling up_simtouchscreen()
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or you will get a crash.
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c. Call sim_tcunininitializee() when you are finished with the
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simulated touchscreen.
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d. Enable CONFIG_DEBUG_INPUT=y for touchscreen debug output.
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4. X11 Build Issues
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To get the system to compile under various X11 installations
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you may have to modify a few things. For example, in order
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to find libXext, I had to make the following change under
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Ubuntu 9.09:
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cd /usr/lib/
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sudo ln -s libXext.so.6.4.0 libXext.so
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5. Multi- and Single-User Modes
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The default is the single-user NX implementation. To select
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the multi-user NX implementation:
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CONFG_NX_MULTIUSER=y
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CONFIG_DISABLE_MQUEUE=n
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6. apps/examples/nxterm
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This configuration is also set up to use the apps/examples/nxterm
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test instead of apps/examples/nx. To enable this configuration,
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First, select Multi-User mode as described above. Then add the
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following definitions to the defconfig file:
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-CONFIG_NXTERM=n
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+CONFIG_NXTERM=y
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-CONFIG_NX_MULTIUSER=n
|
|
+CONFIG_NX_MULTIUSER=y
|
|
|
|
-CONFIG_EXAMPLES_NX=y
|
|
+CONFIG_EXAMPLES_NX=n
|
|
|
|
-CONFIG_EXAMPLES_NXTERM=n
|
|
+CONFIG_EXAMPLES_NXTERM=y
|
|
|
|
See apps/examples/README.txt for further details.
|
|
|
|
nxffs
|
|
|
|
This is the apps/examples/nxffs test using a MTD RAM driver to
|
|
simulate the FLASH part.
|
|
|
|
nxlines
|
|
|
|
This is the apps/examples/nxlines test.
|
|
|
|
nxwm
|
|
|
|
This is a special configuration setup for the NxWM window manager
|
|
UnitTest. The NxWM window manager can be found here:
|
|
|
|
nuttx-code/NxWidgets/nxwm
|
|
|
|
The NxWM unit test can be found at:
|
|
|
|
nuttx-code/NxWidgets/UnitTests/nxwm
|
|
|
|
Documentation for installing the NxWM unit test can be found here:
|
|
|
|
nuttx-code/NxWidgets/UnitTests/READEM.txt
|
|
|
|
NOTES
|
|
|
|
1. There is an issue with running this example under the
|
|
simulation. In the default configuration, this example will
|
|
run the NxTerm example which waits on readline() for console
|
|
input. When it calls readline(), the whole system blocks
|
|
waiting from input from the host OS. So, in order to get
|
|
this example to run, you must comment out the readline call in
|
|
apps/nshlib/nsh_consolemain.c like:
|
|
|
|
Index: nsh_consolemain.c
|
|
===================================================================
|
|
--- nsh_consolemain.c (revision 4681)
|
|
+++ nsh_consolemain.c (working copy)
|
|
@@ -117,7 +117,8 @@
|
|
/* Execute the startup script */
|
|
|
|
#ifdef CONFIG_NSH_ROMFSETC
|
|
- (void)nsh_script(&pstate->cn_vtbl, "init", NSH_INITPATH);
|
|
+// REMOVE ME
|
|
+// (void)nsh_script(&pstate->cn_vtbl, "init", NSH_INITPATH);
|
|
#endif
|
|
|
|
/* Then enter the command line parsing loop */
|
|
@@ -130,7 +131,8 @@
|
|
fflush(pstate->cn_outstream);
|
|
|
|
/* Get the next line of input */
|
|
-
|
|
+sleep(2); // REMOVE ME
|
|
+#if 0 // REMOVE ME
|
|
ret = readline(pstate->cn_line, CONFIG_NSH_LINELEN,
|
|
INSTREAM(pstate), OUTSTREAM(pstate));
|
|
if (ret > 0)
|
|
@@ -153,6 +155,7 @@
|
|
"readline", NSH_ERRNO_OF(-ret));
|
|
nsh_exit(&pstate->cn_vtbl, 1);
|
|
}
|
|
+#endif // REMOVE ME
|
|
}
|
|
|
|
/* Clean up */
|
|
|
|
UPDATE: I recently implemented a good UART simulation to driver
|
|
the serial console. So I do not believe that problem exists and
|
|
I think that the above workaround should no longer be necessary.
|
|
However, I will leave the above text in place until I get then
|
|
oppotunity to verify that the new UART simulation fixes the problem.
|
|
|
|
ostest
|
|
|
|
The "standard" NuttX apps/examples/ostest configuration.
|
|
|
|
pashello
|
|
|
|
Configures to use apps/examples/pashello.
|
|
|
|
touchscreen
|
|
|
|
This configuration uses the simple touchscreen test at
|
|
apps/examples/touchscreen. This test will create an empty X11 window
|
|
and will print the touchscreen output as it is received from the
|
|
simulated touchscreen driver.
|
|
|
|
Since this example uses the simulated frame buffer driver, the
|
|
most of the configuration settings discussed for the "nx11"
|
|
configuration also apply here. See that discussion above.
|
|
|
|
See apps/examples/README.txt for further information about build
|
|
requirements and configuration settings.
|