J.C. Wren 2007/07/17 jcwren@jcwren.com The most recent version of this package may be found at http://jcwren.com/arm Updates: 2007/07/09 - Fixed some spelling errors, modified poorly worded text. 2007/07/09 - Updated info about USB performance under Windows 2007/07/09 - Updated info programming FLASH 2007/07/10 - Added console compilation options to Makefile 2007/07/10 - Added memory dump command to CCI 2007/07/11 - Added IAP commands to CCI 2007/07/12 - Added DAC output to sensors task 2007/07/14 - Added I2C/LM75 support 2007/07/14 - Added watchdog timer support 2007/07/15 - Added SWI demo Significant updates are marked by a '***'. Overview: This package demonstrates using LPCUSB and FatFS under FreeRTOS on the Olimex LPC2148 board, using GCC and newlib. Examples include FreeRTOS queues and semaphores, LPC2148 analog to digital converters (ADCs), external interrupts, the real-time clock (RTC), general purpose IO (GPIO), serial ports (UARTs), and USB. Also included is a newlib syscalls.c that almost completely implements all syscalls.c functions. The package (as built, .hex file included) presents the USB port as a virtual comm port. The virtualized port is used to talk to the console command interpeter (CCI), that allows various functions to be exercised. Alternatively, the package can re-compiled to use UART0 as the console port. If a GPS with NMEA output at 4800 baud is connected to UART1, one of the tasks will parse the NMEA input stream, and display a position report. In addition, the RTC may be set from the GPS time/date. FatFS support is included, and the CCI has several Unix-y commands to manipulate files (mkfs, df, ls, mkdir, rmdir, rm, mv, cp, chmod, and sync). There is also a command that allows through-put testing on the MMC/SD card. This package exists because I wanted to familiarize myself with the LPC2148, FreeRTOS, FatFS and LPCUSB for a personal project, using GCC and newlib (who can afford those commercial packages? Not I). By slightly modifying the resulting framework, I was able to produce a package that others may possibly find useful. Software tools: The package compiles using the arm-elf GCC package. Gentoo users can install this by emerging the 'crossdev' package, then 'crossdev -t arm-elf'. Once the arm-elf verison of GCC is installed, the package can be rebuilt with 'make'. To program the board, the Philips LPC2000 Flash Utility v2.2.3 Windows tool was used. There are Linux based tools for programming the LPC21xx parts, any of which support the LPC2148 should be suitable. It may be normal, but I couldn't get the board to program at speeds other than 19200 and 38400. ProComm was used to talk to the console port on UART0, and HyperTerm to talk to the console port when using USB (Don't get me started on how crappy HyperTerm is. I *DESPISE* this abortion, and figure that Hilgraeve must have pictures of Gates with a goat or something. We can argue about MS quality all day long, but HT has all the "quality" of a 6 year olds first programming project in QBASIC. The only reason it was used was because ProComm can't talk to COM18, which is what the virtual serial port appears as). If using the USB virtual comm port under Windows, the 'usbser.sys' and 'usbser.inf' files may be needed. Often, these files are already on the drive somewhere, and Start->Search->Files can be used to located them. If not present, they are included in the ./Windows directory in the package. Under Linux, 'minicom' should be able to talk to both the serial port and the virtual comm port the USB port appears as. Bertrik's wiki, located at "http://wiki.sikken.nl/index.php?title=LPCUSB", has a note about using LPCUSB under Linux. The default baud rate for UART0 is 115200. The baud rate selected for the USB virtual comm port is irrelevant, and may be any speed. Rebuilding it: Simply typing 'make' should build the entire package. The FreeRTOS modules will emit several warnings about type punned references, which can (safely?) be ignored. If you wish to use UART0 for the console port, edit ./monitor/monitor.c, jump to near line 938, and change the "#if 1' to '#if 0', then recompile. If you wish to change the baud rates for UART0 or UART1, edit ./main.c, jump to near line 62, and change the rates. Any standard baud rate should produce usable results. 'make clean' will clean the project, removing the ./*.hex, ./*.lst, ./*.map, ./*.elf files, and ./common/common.a, along with all *.o and .depend files in any sub-directories. 'make tags' will rebuild the ctags file for 'vi' (and no doubt emacs, if you're one of "them"). Hardware (required and optional): Olimex LPC-P2148 board (required) USB cable (optional) Serial cable (optional) GPS with NMEA output and serial cable (optional) Using it (Windows): For the purposes of these instructions, it will be assumed that COM1 is the serial port on the host PC, a USB cable is connected to the LPC-P2148 board and the PC, and that the Philips LPC2000 Flash Utility V2.2.3 will be used for programming. Please note that Windows 2000 was used, and that dialogs for Windows XP are probably slightly different. If you're using Vista, I'm surprised it can stay up long enough for you to read this document... Connect the RS232_0/ICSP DB-9 on the LPC-P2148 board to the comm port on the PC, using a straight-thru serial cable. Set both the ICSP slide switches (located near the RS232_0/ICSP DB-9 connector) to the 'on' position (towards the DB-9 connector), then press the reset button (located next to the ICSP switches). Configure the Philips utility for COM1, 38400 baud. Click the 'Read Device ID' button. LPC2148 should appear in the 'Device' text field. Note that the device ID has to be read to set the value, as there's a nasty bug in the utility that prevents selecting it from the drop down list. Click the "..." button in the 'Flash Programming' block, then locate and select the 'lpc2148.hex' file, followed by clicking the 'Upload to Flash' button. At this point, the flash image should start being programmed. When it completes, set the two ISCP slide switches to 'off', and press the reset button. The 'LED1' LED should start flashing. If Windows already does not already have the 'usbser.sys' driver installed, a dialog will appear regarding the discovery of new hardware. (I don't remember how the dialog goes, so you'll have to infer your way through this process). When prompted for the driver, navigate to the ./Windows directory, and select 'usbser.inf'. This should install the driver for the virtual comm port that will support the USB port. Right-click on the 'My Computer' icon on the Windows desktop, select Properties, then the Hardware tab, followed by 'Device Manager'. Click the '+' on the 'Ports (COM & LPT), and there should be an entry for "USB CDC serial port emulation (COMxx)" (where 'xx' will be a number). Note the COM port for use with HyperTerm (see previous rant). Start HyperTerm (Start->Programs->Accessories->Communications->HyperTerm) (see previous rant). When the dialog appears, type a name for the connection (The COMxx name is a good choice). Click the drop-down box under 'Connect using'. Select the COMxx port name from the drop-down list. Click 'OK', followed by File->Save. Now click the third icon from the left, which looks like a telephone with the handset on the hook. If all went well, typing 'help' should show a list of commands supported by the CCI. If so, congratulations! You can now play with various commands. If not, there's not much advice that can be offered at this point. *** Baldur Gislason informed me that the Philips Flash Utility has been replaced by by Flash Magic (http://www.flashmagictool.com). I gave this a try, and it worked well enough. It's a nicer interface, but it seems a tad slower. Rather than go into detail how to use it, I'll just say that I set the devce to LPC2148, interface to 'None (ISP)', the oscillator frequency to 12.00000, and checked the 'Erase blocks used by Hex File', and it just worked. Using it (Linux): Eeek! This needs to be written. *** (Richard T. Stofer says that Debian plays nicely with the LPCUSB code. with the virtualized comm port appearing as ACM0. 'minicom' can talk to this port). Hardware thingies: The two pushy buttons on the LPC-P2148 board (B1 and B2) enable and disable LED2. Pressing B1 should light LED2, pressing B2 should extinguish it. These buttons are connected to the EINT2 and EINT0 lines, respectively. The associated code demonstrates handling an external interrupt, and toggling an I/O pin in the interrupt service routine (ISR). The potentiometer, AN_TR, is connected to ADC0, channel 3. The 'sensors' task checks the value every 100 milliseconds. The software divides the pot into 4 zones, each covering about 1/4 of the range the pot may be rotated. When the pot is fully counter-clockwise, LED1 will be on for 200 milliseconds and off for 800. When the pot is moved to the 2nd zone, the on/off times become 400ms/600ms. The 3rd zone has on/off times of 600ms/400ms, and fully clockwise is 800ms on, 200ms off. LED1 is controlled by the LED task. This is a lower priority task. Each time a single on/off cycle has completed, it's message queue is checked to see if the blink ratio times should be changed due to the AN_TR pot changing zones. LED2 is controlled by the B1 and B2 pushy buttons, as mentioned above. *** The DAC output on the AOUT pin changes every 100 milliseconds by 1/64 of the range of the DAC (0.0515625 volts). The generates a sine wave with a period of 12.8 seconds, or 0.078125 Hertz. Hang a 'scope or DVM on the AOUT pin to see the change. *** The I2C routines are setup to talk to a LM75 temperature sensor. These can often be found on old PC motherboards, or as samples from National. The I2C demo code is a simple polled approach, and does not take advantage of either interrupts or the I2C state machine. The 'lm75' CCI command allows reading and writing of the configuration, THYST and TOS registers, and reading of the temperature register. The 'lm75 mode' command determines if the registers are read using an I2C repeated start sequence instead of an I2C stop then I2C start. Repeated starts are faster, and allow for holding the I2C bus in a multi-master environment. The default is repeated starts (mode 0). There is one potential spot for the code to hang. If the I2C bus fails to release SCL (if the I2C device is powered down, perhaps), it will hang waiting for the status interrupt bit to change. Any hard while loops should be wrapped in a counter or timer check. *** Demo now includes watchdog timer example. 'wdt test' enables the watchdog. If no command is typed for 10 seconds, the system will reset. 'wdt status' can be used to examine the current watchdog state and the RSIR register (which allows determination of why a reset occurred). Use 'wdt clear' to clear the RSIR status. Sort of hardware thingies: The SWI demo code is taken from several different projects, and culled down into something I felt was more readable, and better for explanations. The CCI 'swi' commands allow setting the state of, turning on, turning off and toggling LED2. The commands starting with 'a' use the assembly interface (assembly sequences are used to affect LED2), whereas the commands starting with 'c' manage LED2 in C. Note that the pushy-buttons also toggle LED2, so there can be some interaction. CCI commands: If you're a Linux user, most of the file commands are fairly self explanatory. If you're not a Linux user, you should be, because it's better on our side of the fence. The file commands require that a MMC/SD card be installed in the MMC/SD slot. BEFORE USING THE FILE COMMANDS, USE THE 'mount' COMMAND TO MOUNT THE MMC/SD CARD. Note that the first partition on the MMC/SD card will be mounted, and this is the only one supported. It must be a FAT12, FAT16 or FAT32 partition. If the MMC/SD card is not formatted with a FAT12/FAT16/FAT32 file system, you can use the 'mkfs' command to create it. If anything already exists on the card, 'mkfs' will wipe it out. Note that while a fairly good success rate has been obtained with the cards on hand, one Sandisk 64MB MMC card did not work. Not sure why, but the MMC drivers are probably not handling something quite right. 'cpcon ' allows a text file to be created from the CCI. Enter text until you're bored, then type ctrl-d save and exit. Note that whatever characters are typed are saved into the file verbatim. This means that characters like backspace are actually put into the file (feel free to improve that code...) Before creating any files, you may wish to set the system date, so that files are date/time stamped properly. If a GPS with NMEA output is connected to RS232_1, you can use the 'gps' command to verify the serial connection, that NMEA data is being parsed, and that the GPS has acquired (required for the date/time to be set). If you have no GPS attached, you may enter the date and time as parameters. 'settime 2007/07/08 22:51:25' will set the date and time to July 8th, 10:51pm and 25 seconds. No timezone info is applied, so date/times acquired from the GPS are UTC. Date/times set manually may be set to local time or UTC (or something completely random, if you're into that). The 'thruput' command allows measuring MMC/SD read and write performance. Eight file sizes are used: 1K, 8K, 16K, 64K, 128K, 512K, 1MB, and 2MB. A temporary file is created on the MMC/SD card. Measurements can be done one of four ways: 'noints' (fastest, but disables all tasking), 'normal' (CCI task priority is not changed, no tasks are suspended), 'suspendall' (all tasks are suspended, no context switches made, but 10ms interrupts still runs), and 'high' (CCI task is elevated to highest priority for duration of test). Oddly, writes are faster than reads when not using the 'noints' mode. I have not yet researched why. Leaving interrupts enabled *seriously* impacts the file system performance, nominally by a factor of 20. *** Richard T. Stofer noticed that this slow down only appears when using the 'usbser.sys' drivers under Windows. When using the Linux ACM drivers, or when using UART0 as the console port with the USB cable disconnected, this problem does not occur. We can only assume that the Windows driver sends lots of (needless) packets (yet another reason to switch to Linux!) The 'date' command will report the current date/time from the RTC. If you have an external 3V battery plugged into the BAT connector, the RTC will preserve it's values across power-downs. Regardless of the battery presence, date/time will be preserved across resets (as long as power is not removed). The 'sensors' commands reports very little useful information. The sensors task executes every 100ms, and samples the ADC connected to the AN_TR potentiometer. Every time the task runs, the sensors counter is increment by one. If the AN_TR pot is adjusted far enough to change the zone, the ADC changed value will increment. See the section above on the pot. The associated code demonstrates running a high priority task with a constant execution frequency, sampling an ADC, and sending a message to another task. The 'mem' command displays the various tasks running, and the amount of unused stack available to each task, along with the task priority and such. The associated code demonstrates the 'vTaskList' RTOS call. Note that in a 'real' system, leaving the task trace code enabled (configUSE_TRACE_FACILITY) imposes a slight penalty on context switches, which may be undesirable. The 'iap' commands allow experimenting with the In-Application Programming (IAP) code. The demo code demonstrates preparing, erasing, writing, blank checking, and retrieving processor ID and boot loader version numbers. IAP deals with primarily with sectors. In the LPC2148 (which has 512K of flash), there are 4K and 32K sectors. The CCI will not allow selecting sectors that are used for code. The 'fss' command will find a safe sector to use with the 'iap' commands. Once a safe sector is known, you can erase and fill this sector. The blank checking will work on any valid sector (there are 27 in the LPC2148). The IAP_COPYRAMTOFLASH (writing to flash) is demonstrated by the fill command. Whatever size the sector selected is, the 'fill' command will fill the entire contents with the supplied byte value. The 'md' command can be used to dump the sector contents to see the effects of 'erase' and 'fill'. The 'stoa' command is used to convert a sector number to an address for 'md'. It is strongly recommended that you become familiar with the section on IAP in the LPC2148 datasheet before using these commands. The IAP prepare and compare functions are not CCI accessible. These are handled internally by the erase and fill code. MMC/SD notes: As mentioned above, I have a Sandisk 64MB MMC card that the MMC drivers can't seem to recognize. I have 4 other cards that work fine, one of which is an MMC, the other three which are SD. I'd like to resolve this issue. During the 'thruput' test, when interrupts are left enabled, I have on rare occasions seen a read or write error occur. I believe this is because a context switch is taking place during some time critical code. Ideally, interrupts would be disabled. However, disabling interrupts makes an RTOS merely an OS. The 'real-time' part means predictable response to interrupts, and the executing time-critical tasks on-time. In this code, the MMC/SD code is non-reentrant (only one task may read/write the card), and not time critical. If multiple tasks have to write to disk, this would currently have to be handled by creating a task that communicates through queues to other tasks, and manages the MMC/SD card. Note that if a GPS is connected, a message that a NMEA checksum could not be found may occasionally appear. While the actual test is being run, the GPS task is not processing messages, and the serial buffer overruns. When the task is allowed to run again (between tests), partial NMEA messages that cannot be parsed may be present, resulting in the error message. GCC notes: This code was compiled with -O3. This results in code that's about 16K larger than -Os, but has a measurable impact on the MMC/SD card throughput (not large, but it can be seen). I went with -O3 because with 512K of FLASH, and 144K or so used, there's plenty of room. I'm not sure what the compiliation options for newlib are. 'crossdev' compiled those, and I suspect it was with -Os, since embedded systems generally tend to consider size over speed. GCC is an amazing package. I'm used to running into compiler issues with many of the micros that I work with (SCCS, Microchips C18, etc). It's so nice to have a compiler that produces code without problems, and doesn't have idiot front-ends that can't even get the sign on an enum correct (at least Microchip got it right for the dsPIC and PIC24 parts, which used GCC. C18... Don't go there...) There's a trick to writing Makefiles, and I don't have it. It's an arcane art, and involves the slaughtering of goats, black candles, and full moons. The Makefiles I did write are very basic, and use recursion ('Recursive make considered harmful!'. Foo on that. Worked for me). I tried a couple of approaches, and either everything built anyway, or nothing built at all. To make the linking work, as files are compiled, they're dumped in to ./common/common.a, and main.c is linked against that. So far, the expected bite on the butt for doing it this way has not happened. It would be really neat to have Makefiles done right. Alas, I don't know how to do it right. So if the common.a approach looks really ugly to you, that means you probably know how to write Makefiles that handle sub-directories correctly, and you can tell me how it should be done :) (With examples!) Notes on newlib: I wasn't happy with the newlib syscalls.c that was included in the original LPC2148 port. I more or less completely rewrote this, with the exception of _sbrk(). _open() can open the serial ports, USB port, and FatFS files. All supporting functions except _fstat() work (see FatFS complaint at bottom). Newlibs method of converting a file descriptor (as returned by _open()) to a slot (which points to assorted info for that fd) uses a loop. As this is done on EVERY read and write call, unnecessary overhead is added. I fixed the find_slot() code to cache the last fd, and if it's the same on a subsequent call, the search is skipped. _open() is VERY suspect, in that remapping of FatFS f_open flags don't correspond cleanly to Unix's open() call. I handle the four common cases correctly, but lesser used ones may result in a EINVAL errno on open. Opening FatFS files is expensive, RAM space-wise. Each open file uses a FatFS FIL structure which contains a 512 byte buffer, plus some additional space. With 32K on a LPC2148, and 20K being used for the FreeRTOS heap, that leaves 12K that has to be used for the stack, heap, printf(), etc. Don't go wild opening files, and be sure to close unused files to free the space. Use open() instead of fopen() whenever possible, as the FILE structure has it's own set of buffers. There may be a way to figure out how much heap and stack have been used under newlib. If there is, I haven't figured it out yet. I'd really like to be able to make a newlib or system call that returns total space available, heap used and stack used. Since stdout and stderr point to same place, it's wise to close stderr and set stderr to stdout. Only functions like assert() use stderr, so intermixing stderr and stdout shouldn't be a problem. Especially since there's no redirection of I/O... Header file for LPC2148 (lpc210x.h): The original LPC2148 header file was very lacking. Not only were individual bit fields generally not defined, major peripherials weren't defined. As a result, FreeRTOS, LPCUSB, FatFS and newlib all used local defines. Worse, some of these were simply "SOMEREG = (1<<31)". Great. What does bit 31 do? Personally, I feel the best way is to define structures AND #defines. It's good that a structure has an element called 'CLK', but setting CLK to 0 doesn't give a hint as to what clock mode is being set. A #define for XXX_YYY_CLK_BIPHASE, then saying XXX_YYY_bits.ClkMode=XXX_YYY_CLK_BIPHASE is a lot clearer. I defined a mess of #defines, with the majority matching the names in the datasheet. There were few that become triplely redundant, such as WD_WDFEED_WDFEED1. This was reduced to WD_FEED_FEED1. The characters prior to the first underscore define the module, with the next set the defining the register name. Subsequent fields define the bit field name, and then possible variations. What I don't like about using #defines to define the registers is that the programmer needs to know if the bits being affected need to be AND'ed or OR'ed. Structures neatly solve this problem, but defining all the structures takes a lot of work (yea, IAR has already done that, but it's not legal to just swipe their nice headers). With one exception I'm aware of (in the TODO section), I rewrote all the code that sets registers to use the values in the lpc210x.h file. While I doubt it makes the code more portable (will NXP change block addresses, but leave bits the same? Probably not), it does make it more readable. One of the last major areas to be completed is to pull the USB protocol engine #defines into lpc210x.h. These are currently defined in one of the USB header files, and have poor name scoping (does "ACK_STAT" tell you what module or register it applies to? No.) Software notes: All copyrights are by their respective authors. FreeRTOS is by Richard Barry. LPCUSB is by Bertrik Sikken. FatFS is by ChaN, with sections by Joel Winarske. Other sections of code may have come from the intarweb, and have respective copyrights, indicated or not. Any code that I personally authored is free for public consumption, unemcumbered by any copyrights, etc (that crap is just too confusing. BSD? LPGL? GPL3? Who the hell knows...) I've re-formatted a good deal of code in LPCUSB and FatFS. Some portions were re-written, others simply re-formatted to my coding style (which I jokingly refer to as JC1). I have occasionally whacked comment blocks that I didn't really think indicated what the code did, or was redundant. I probably whacked some text with copyrights in the process. This in no way reflects an attempt to claim the work as my own, or to otherwise dishonor the original authors. As Isaac Newton (more or less) said, "If I have seen a little further it is by standing on the shoulders of Giants." Without the work of these most excellent people, this code would not exist. Most of the reason for my re-formatting is my way of understanding the code, going through it section by section. It's good because I have a better understanding of it, worse because it makes drop-in replacement with updates from the authors more difficult. The most affected area is the SPI handling in the FatFS code. Originally named 'mm_llc_spi1.c', I felt this was not cleanly integrated, so I rewrote it. Maybe it's not better, but it is different :) The FreeRTOS code is almost completely untouched, except for moving an #if around that allowed compiling the trace code (configUSE_TRACE_FACILITY) without requiring the task suspend code (INCLUDE_vTaskSuspend). In the end, this was probably irrelevant, since I compiled the task suspend code in anyway. Things I wish were different: A collection of random little thoughts of things I wish were different. These are just MY opinions, based on the way I do things. It's not to say the original authors were wrong. It's just the way I'd make things, if I were smart enough to write this stuff from scratch. Most people probably shouldn't even read the following list... While FreeRTOS attempts to isolate the user from system data structures, it's a little *too* aggressive. These typedef'ed structures should be in a header file, so applications can at least use sizeof() to help determine memory allocation. Everything is done through recasted void* pointers. It would be neat if FreeRTOS had a xDelayTaskUntil() that also took one or more queues as a blocking item. I want to run a task every 'n' milliseconds, but if something shows up in a queue, process it early. Perhaps this could work like Unix's select(). Or perhaps a variadic function that takes xQueueHandles as parameters. I dont' care for FreeRTOS's use of portBLAH typedefs for portable types. The world is pretty used to U8, U16, N32, and BOOL for unsigned char, unsigned short, signed int, etc. FreeRTOS also seems to require declaring too many things as 'signed', which should be a default. I'm sure this is done for portability, but I find the types are not as intuitive as they could be. Another minor itch is that all function names and types start with 'x'. I would have preferred 'freertos', or better, a user-definable one, via a #define macro. I think programmers forget that their package may be integrated into a larger system, and while their naming convention works well for their purpose, it may not scale well. FatFS and LPCUSB are guilty of this as well. FreeRTOS has a couple errors in several of the modules regarding type punning. I understand what type punning is, but I don't know how to fix it safely. Perhaps RB will fix those up in the next release. FatFS changes return types too often, particularly for errors. There's the errors from the SPI routines, the MMC routines, the disk routines, and the top layer FatFS code. There should be unified errors for everything, so that errors can be cleanly communicated up the stack. FatFS can't go from file descriptor to filename. I haven't figured out a clean and reliable way to map a fd back to a filename (FatFS f_stat() needs a file name). I thought about malloc()'ing space in the openFiles_t structure and copying the filename when the file is opened. However, paths can get up to 128 characters, and only _fstat() needs that information. This seems very wasteful. FatFS wants the user to provid the get_fattime() function. FatFS should really have a file for locally provided functions. It's already specific to the SPI or IDE port implementation. As such, it should be stubbed out to return 0 if the function isn't provided, or allow the user to implement in the platform specific file (basically, an equivalent of syscalls.c, but internal to FatFS). FatFS has naming conventions that I don't like. It exposes too many internal function names that should be declared static. Structure names like 'FIL' are ambiguous, and too likely to collide with other libraries. Functions should be preceed by the supporting module or library. All FatFS functions should be in the form of fatfsOpen, fatfsClose, etc. LPCUSB is not organized quite the way I'd do it. The USB protocol engine defines need to have their names modified and moved into the lpc210x.h. Newlib lacks certain calls on the ARM7 platform. sync() and chmod() do not exist, while mkdir() does, but wit no corresponding _mkdir() support in syscalls.c. Returning ENOSYS is easy enough, and doesn't take but a few instructions. Providing support for a wider range of calls would be good, taking into mind things like FatFS that provide file system support, etc. The Olimex board COMPLETELY lacks documentation (at least, that I've been able to find). It's up to the user to guess what the slide switches are for, etc. It's probably pretty obvious to someone who's used the LPC2000 parts before, but if you're buying a board to get started, you have to waste time figuring out how to use it. Even a simple Xerox'ed sheet would have been sufficient. The Olimex board also lacks the ability to control the BSL line from the serial port. Reset works, but without being able to flip the BSL switch, it has little value. The buzzer on the Olimex board is useless. Had it been connected to one of the PWM outputs, some simple sound synthesis would have been possible. At best, it demostrates you can toggle I/O pins fast enough to make noise. However, unless you want clicks in the output, you have to disable interrupts. And why *two* port pins? One would have been sufficient. I would have preferred to have two more LEDs, rather than the buzzer. TODO: ./FreeRTOS/portable/GCC/ARM7_LPC2000/port.c uses local defines for timer control Finish rest of syscalls.c functions (fstat ()) Some modules (USB) still have local #defines for hardware (protocol engine) Add interrupt driven I2C that uses I2C state machine Add FIQ demo