Sunday, February 9, 2014

AT89LP6440 Flashing

For the Microcontroller Comparison I have been trying to get the AT89LP6440 to work. When I sampled the chip I thought it could be programmed over serial with an FTDI cable like the DS89C450, but it turns out that it needs a parallel port. There are adapters and programmers that will simulate a parallel port over USB but I don't want to buy one for a chip that I might not use much in the future.

As a workaround I used the FTDI cable to bitbang the SPI interface. This was tricky because I had to write a whole new loading program instead of relying on the program Atmel supplies. Thankfully, they provide very good documentation of the ISP specification. Bits are sampled on MISO on the falling edge of the clock and MOSI is sampled on the rising edge. My first version of the program worked well but could only upload about 100 bytes of firmware per second. Part of this is due to reading MISO every clock cycle, which is not always necessary. By splitting reading and writing into different functions and sending pin states in groups instead of individually, flashing is much faster. There is a bug, though, that randomly gives a wrong byte when I try to read from the chip to verify the firmware. The wrong byte is always at a different address and sometimes the verification completes, so I know the AT89LP6440 has been programmed properly. I wasted about a week trying to tweak the program and saw that the D2XX drivers supplied by FTDI are unreliable and pretty buggy (at least when used under Windows 7 for bitbanging). This particular problem could be with the chip but several of the other D2XX functions I tried didn't work very well either. The same problem happens with both synchronous and asynchronous modes. There is an open source library called libFTDI but I didn't get very far with it because installing the driver for it would mean losing the virtual COM port you get with the FTDI driver. The next step would be to program the chip using another microcontroller connected to the PC over UART but I don't want to waste any more time on this chip since I am unlikely to use it for anything after the microcontroller comparison.

You can download the program here: AT89Loader. Flashing seems to work with no problems but verification occasionally fails.

Monday, February 3, 2014

DS89C450 High-Baud Flashing

As I mentioned in my last post, I have been using the DS89C450 lately to do some tests. It has a serial program loader in ROM used to program the chip over UART. The baud rate of programming is dependent on the crystal speed. Some crystals, even fast ones, only work with low standard baud rates and some don't work at any of the standard rates. To understand why, we should look at what baud rates the loader accepts. The User's Guide gives an equation for this:

Baud rate = Crystal Frequency / (192 * (256 - Timer Reload))

The loader tries these values for Timer Reload:  FF, FE, FD, FC, FB, FA, F8, F6, F5, F4, F3, F0, EC, EA, E8, E6, E0, DD, D8, D4, D0, CC, C0, BA, B0, A8, A0, 98, 80, 60, 40. The resulting baud rate must match the baud rate used by the programming computer to within 3%. Using this equation we can see that some common crystals such as 12 and 20MHz only fall within the 3% limit for a few of the slower standard baud rates.

This limit can be overcome, however, by using a non-standard baud rate. Neither the MTK program supplied by Maxim nor Hyperterminal can use non-standard baud rates, but some terminal emulators like uCon can. The above equation can be used to calculate the ideal value. In my case, a 20MHz crystal with a Timer Reload of FF gives a baud rate of 104,166. At this speed I could connect to the chip but not program it without errors. Using the next value of FE for Timer Reload gives 52,083 and at this speed I could connect and program the chip successfully. This is big a improvement over the previous maximum baud of only 4,800!

Another great function of uCon is scripting. Scripts can be saved and assigned to a button. The following script lets me erase the DS89C450 and upload new firmware with just one button click (I usually compile programs to "temp.hex" to make scripting easier):

SET PROMPT >
SEND "K"
SEND -n "L"
SET PROMPT G
FSEND "temp.hex"

Sunday, February 2, 2014

Microcontroller Showdown, Part 3

The next chip I compared was the DS89C450 from Maxim. This is a single-cycle 8051 with clock speeds up to 33MHz. The other single-cycle 8051 I wanted to test is the AT89LP6440 but I wasn't able to program it with an FTDI cable. It expects an SPI interface based on a parallel port and I do not know how to get it working with the FTDI cable.

At first I had a lot of trouble getting the DS89C450 running with the flashing software supplied by Maxim. It just would not connect no matter what crystal or capacitor combination I tried. After a little digging I found out that the baud rate depends on the crystal and that 4800 is the max for 12 and 20MHz crystals. Unfortunately, the flashing software only supports 1200 and 9600 or higher bauds. At 1200 baud I was finally able to connect successfully but the chip returned an error when I tried to load firmware. After more digging it seems the problem is caused by using an FTDI cable instead of a real serial port. I can't really hold this against the manufacturer, though, since the chip and software are over 10 years old at this point. Next I tried connecting over Hyperterminal at 4800 baud and this worked great. The interface for communicating with the chip is actually kind of slick. It gives you a prompt you can type commands into and responds back to your input. Loading firmware at 4800 baud, however, was a real pain. If I decide to seriously use this chip, I will definitely track down a crystal that lets me connect at 57600 baud.

The results of the tests are after the break. I ran them with a 20MHz crystal and scaled the results for what they would probably be with a 33MHz crystal. For compiling I used SDCC. This compiler is new to me but it seems pretty simple to use. In place of -O3 I used --opt-code-speed and for -Os I used --opt-code-size. There wasn't really a difference in the results though. As you can see, it adds 8 bit numbers even faster than the LPC1114, 16 bit numbers about as fast as the MSP430, and 32 bit numbers almost twice as fast. It is also much faster at multiplying than the MSP430, which was a surprise to me. Out of curiosity I looked at the 8051 instruction set and was quite surprised to learn that it has 4-cycle multiplication of 8 bit values. The rest of the instruction set and architecture seems very straightforward and I imagine it would be fun to write assembly code for this chip. Division and shifting are pretty slow. GPIO, however, is very fast. Each pin is mapped to its own byte in memory. This seems like a simple feature and I wish more chips had it. With this the chip can bit bang almost as fast as the LPC1114 can with masks. The real test of the chip, though, is BCD calculations and in this it was pretty disappointing, running 2-3 times slower than the MSP430. For these tests all the data was stored in the on-chip external RAM (xdata). This is slower to access but it was necessary to store it here since the internal RAM holds less than 100 bytes. I also tried storing it in the idata section available in 8052 compatible chips like this but that was even slower. It looks like I won't be using this chip for any calculator designs but I will keep it in case I do a project that needs an external memory interface or memory mapped peripherals.