Basically , I want to know What an ARM Simulator is ? IS it something like an Assembly language simulator ? If so what are the differences in comparison with Verilog Simulators?
Your question is quite broad/vague. but here goes.
An arm simulator, from the context of what you are asking, is likely an instruction set simulator. Software that just like a processor decodes the instructions, keeps track of the registers, and simulates the execution (if an instruction says add 1 to r1 then you have a variable in software that represents r1 and you add one to it).
A verilog simulator, is not really any different just a different language. verilog is a hardware design language, before you can simulate it you need to compile it. Just like any other high level language it needs to be compiled down to something related to the target. simulators will have their own target logic blocks. The verilog is compiled down to these blocks then that logic is simulated, not unlike the arm simulator. For each clock cycle you update the inputs to each logic element based on the output of the connected block from the prior cycle, then evaluate each logic element and determine the outputs. repeat forever. for each verilog simulator you have a different target at its core, partly why you (can) get different results from each simulator for the same code. Likewise when you compile for the actual target, fpga, asic, etc, it is compiled differently than the simulator (or can be, depends on the environment, simulator, etc).
There is no magic at all to any of these simulators, an instruction set simulator is generally easy to write, a worthwhile task for anyone wanting to get a good strong knowledge of an instruction set or how computers work (start with something small like lc-3, should take less than half an hour). A FAST simulator, that is another story, but a FUNCTIONAL simulator is fairly easy to write. Once compiled to a netlist of simple logic components a verilog simulator is probaby easy as well the biggest task though is the volume of signals and items to evaluate and parsing the code to get at the list of signals and logic functions and who is tied to what. Not as easy as an instruction set simulator, but quite understandable how it works and what the task would be...Verilator is pretty cool as it turns it into lines of C++ code, MANY lines, and a good sized project can take many hours to days to compile even on a screaming machine. (hint turn off waveforms to cut the compile time way down). But the task is understandable when you look at what is going on.
For the life of me I can't make a timer for PIC18 or precisely PIC18f87j11. All I want to do is to have a counter that increments every 1 second. I just want to monitor how long PIC18 been running in terms of seconds.
Most of the tutorials out there are for PIC16 and are in assembly. I am trying to do this using C programming. For someone who is beginner I understand better if I see examples, so without examples I can't progress.
please someone show me an example, thank you!
To begin understanding timers you will need to have a look at their documentation. I suggest searching the manufacturers website. There are 5 timer available. If you use Timer0 which is either a 8 bit or 16bit timer. You will need to set the correct configuration for T0CON. Also you will need to have correct interrupt settings (INTCONbits), so a an event can be generated by interrupt service routine once timer expired.
You will most likely need to calculate the prescale value you require for correct timing, in your case 1 second. It does depend on FOsc: Here is a tutorial
Here an example of C code using MPLab and another one based on MPLab and hi-tech compiler. It is not for same chip, however it is based on PIC18F family.
It's been a awhile since I have visited PIC18F, so if any correction required, please do so.
If you use HIGH-TECH compiler, you can simply use its special function for close, open, read and write timers modules in below directory:
...\HI-TECH Software\PICC-18\9.80\sources\plib\Timers
According to your microcontroller name, you can figure out which version of these function is written for your microcontroller. So for first step, open pconfig.h file and search your microcontroller name to see for every module which version is fit to your microcontroller registers.
Good Luck
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I'm trying to familiarize myself with the embedded field, but also have limited resources in terms of time and equipment to buy.
What's a good language to wrap my head around embedded, without investing too much time leaning an embedded-specific language? I'm most familiar with PHP, Java, Actionscript, but unfortunately know very little C. I remember reading somewhere that someone used PERL to program embedded systems, but not sure if that's really possible.
Can learning be done without needing to buy chips, etc. via simulators or such?
Can someone recommend a simplified roadmap to show how one would get sarted? I'm a little unsure where to even start.
You need to know C (but every programmer needs to know C !)
Most of these platforms have a simulator/emualtor, but since the point is to learn real applications and real problems ( which are all to do with real world timing issues) then you want a real board.
You probably also want an oscilloscope (a very cheap n'th hand slow analogue scope will do) and have some idea how to use it.
Easiest way in is probably Arduino, perhaps more professional but a little harder is launchpad MSP430
There are a few embedded programming lessons that carry over from one platform and style to another, but it is really a broad field. Different processors can require very different tactics, and different applications can dictate both different firmware design tactics and different microcontrollers. Here's some stuff to get you started....
msp430
Texas Instruments has several very inexpensive USB development kits which they call EZ430 and are based on their MSP430 family of micro-controllers. The simplest one has an msp430 f2013, which has 2K of flash program space, 3x128 bytes of usable user flash (another 128 byte page exists, but it's special), 128 bytes of RAM (yes, 128 bytes but it's enough for lots of things), and 16 CPU registers (some of these are special purpose like the Stack Pointer, Instruction Pointer, Status Register, and maybe one or two more). MSP430s also have several memory mapped special function registers which are used for configuring and controlling the built in peripherals. MSP430s are von Newman processors, so everything lives within one address space. These cost about $20us for both the programmer and a removable tab (pc board) containing the msp430 f2013. For about $10us you can get 3 replacement tabs with msp430 2012, which is pin compatible with the 2013 (mostly) and has a few different peripherals. These tabs have an LED, a button, and several large vias (holes in the pc board) which are connected to the pin of the processor. These vias are easy to solder wires into even if you have never soldered before -- due to capillary action the vias just suck the molten solder up and while it's hot you can just jab the end of your wire in there.
They also have a couple more similar kits with 802.15.4 radios. Even if you aren't interested in the radio you may still be interested in these because their programmer also has a UART pulled over from the removable tab and are compatible with the tabs used on the other kits mentioned above. These kits also contain at least one extra programmable board and a battery pack for it. (one of these kits may contain more, but I don't have mine with me right now, and not going to look it up).
They also have a kit that has a programmable watch as the target platform. I've never had one of these, but they have a display, accelerometers, and several other cool things, but this may overwhelm you for your first project. I'd suggest one of the previous kits to get you started with MSP430s.
You can get free C compilers and development environments for MSP430s in the form of IAR's Embedded Workbench kickstart (4 kb program space limited ) IDE, Code Composer Studio (also limited program size, but higher limit, I think), and gcc/gdb for the MSP430. IAR's kickstart is pretty easy to get started with quickly, though it's not perfect. You may find that you have to shut it down, unplug your USB EZ430, restart IAR, and plug back in to get it going again. Or maybe some different order will work better for you.
TI also provides many examples in badly named files (all of their downloadable files go out of their way to be badly named). Be warned -- similar MSP430s may have different device control register interfaces for similar peripherals, which can be confusing. Make sure that any document or example you are reading really does apply to the microcontroller you are using.
other small systems
There are many many other processors families and kits that you can go with, and you should probably at least know a little bit about them.
AVR -- Atmel's 8/16 bit Harvard architecture. Harvard refers to separate address spaces for code and working memory. It has 32 8 bit registers, some of which may be used in pairs as 16 bit registers. It's a very popular and pretty cool processor. Some of the smallest ones only have registers with no extra RAM, which is scary. Atmel also has an AVR32 which isn't at all the same as the AVR. Unless you make use of an existing bootloader capable of loading your new code you will need to get a JTAG unit for these.
8051 -- This is old as the hills and a pain in the butt to use until you finally understand it. It is an 8/16 bit processor, with many more limits on how you go about doing 16 bit math and only has 1 pair of registers which can act as a pointer. It has 3 separate address spaces (stack, global memory, and code) and lots of odd (compared to other architectures) features. The low level stuff might not mean much to you if your are programming in C except that very simple C operations can turn into much more code than you thought they would. You don't want to start on one of thise, most likely.
propeller -- Parallax's very interesting multi-core processor which is very unlike other processors. It has several cores which act mostly independently and can be used to simulate peripherals or do more traditional computational tasks. I've never used one of these, though I'd like to. Just never had a task that seemed to fit it. They have their own high level language to program them as well as the processor's assembly language.
larger systems
After you get out of the 8/16/24 bit processors you start to blur the lines between embedded and desktop level programming, even if it is technically embedded.
AVR32 -- There are 2 main versions of these. One is a Harvard architecture and the other is von Newman. The von Newman version is essentially a better ARM than ARM, but it's not as popular as ARM. As near as I can tell it was designed with "run Linux" in mind, though not tied to it in any crazy way. You used to be able to get cheap development boards for these and code is often almost as easy to load as copying files from one PC to another, though you will probably make use of uboot and tftp to do some work. JTAG is only needed when you mess up the boot loader. I think all of these have support for native JAVA acceleration. www.AVR32.org
ARM -- The most popular embedded processor. There's many versions of these. Some don't have an MMU (memory management unit) and some do. There's too much to say about them. Some version have native JAVA acceleration, though I think that the ARM lords don't freely tell all of the details of how to use it, so you have to find a JVM which knows how to use it. Many vendors make them, including Atmel, Freescale, Intel, and many others.
MIPS -- A very RISC processor. The RISCiest.
There are many others.
Programming styles
I could write 3 books on this but the general rule is make things as simple as the application can let you. An exception to this is that if you can easily make use of an operating system you might want to make use of it if it simplifies your task.
The first thing you need to know when answering this question is "WHAT IS" an embedded system? A GENERAL definition would be a computer system which is dedicated to a single specific purpose. This doesn't limit the type of hardware you can use, as matter of fact "Embedded PCs" have been used for years. The QNX realtime OS has existed since the early 80s and been used in industrial PCs for embedded applications for years. I've personally used in control systems for steel mills XRAY thickness gages. On the other hand I currently use TI DSPs without any OS support and only using 256K of Ram. Another example would be the key fob for your car. Old ones used to use a PIC microcontroller from Microchip. (That's actually the company's name.)
Some people call the IPhone an embedded system, but due to the fact you can load applications to do just about anything I tend to say it's a palm top computer with phone capabilities. An OLD DUMB cell phone that is just a phone, not PDA is an embedded system. That's just a bit of philosophy.
As a general rule there are a handful of concepts you need to grasp for embedded systems programming, and most of them can be explored on a PC.
EDIT:
The REASON why C or C++ is recommended is C itself was designed to do systems programming. C++ maintains all it's advantages but adds capabilities for OOP programming. Some ASM maybe required in some systems. However a lot of chip vendors, such as TI, provide tools basically make it possible to do your entire system in C++.
:END EDIT
ALOT of simple embedded systems look more or less like this:
While(true) // LOOP FOREVER... There is no command prompt
{
// Typically you want I/O to occur on fixed "timebase."
wait(timerTick);
readDigitalIO(&dioStruct);
readAnalogIO(&aioStruct);
// Combine current system state with input values
// and do some useful calculations. (i.e. Analog input to temperature calc)
Process(dioStruct,aioStruct,&CurrentState);
// This can be a serial output/audio buzzer/leds/motor controller
// or Whatever the system REQUIREMENT call for.
driveOutputs(CurrentState);
// The watchdog timer resets your system if it gets stuck.
petWatchDogTimer();
}
There is nothing here that you can't do using the PC. (Well a PC that still has a parallel port anyway. Which is a more or less just a DIO port.) On a simple system without a os this might be all there is. On a RTOS based system you may have several task that all look somewhat simalar to this, but pass data back and forth between the tasks.
The interesting parts come when you have to interface to the hardware on you're own, the first job I had out of college was writing a device driver for a data acquisition board under QNX.
Basic concepts of dealing with hardware, or device drivers (Which you can experiement with by hacking Linux device drive code which is freely avaliable.), most hardware looks to the programmer like just another memory address. This is called "Memory mapped I/O." What does this mean? Lets use a serial port as an example:
// Serial port registers definition:
typedef struct
{
unsigned int control; // Control bits for the port.
unsigned int baudDiv; // Baud rate divider.
unsigned int status; // READ Status bits/ Write resets fifos;
char TXdata; // The head of the hardware TX fifo.
char RXdata; // The tail of the hardware RX filo.
} serRegs;
// Using the volatile keyword to indicate the hardware can change the value
// independantly from the software.
volatile serRegs *Ser1 = (serRegs *)0x8000; // Hardware exists at a specific location in memory.
volatile serRegs *Ser2 = (serRegs *)0x8010; // Hardware exists at a specific location in memory.
// Bits bits 15-12 enable interupts and select interupt vector,
// bits 11-8 enable,bits 7-4 parity,bits 3-0 stop bits.
Ser1->status = 1; // Reset fifos.
Ser1->baudDiv = CLOCKVALUE / 9600; // Set the baudrate 9600;
Ser1->control = 0x1801; // Enable, 8 data, no parity, 1 stop bit.
// Write out a "OK\r\n" message; (Normally this would be a loop.)
Ser1->Txdata = 'O'; // First byte in fifo Transmission starts.
Ser1->Txdata = 'K'; // Second byte in fifo still transmitting first byte
Ser1->Txdata = '\r'; // Third byte in fifo still transmitting first byte
Ser1->Txdata = '\n'; // Fouth byte in fifo still transmitting first byte
Normally you would have a function or an interrupt handler to handle TXing the data, but for example I wanted to point out that the hardware is working while the software keeps going. Basically hardware works like, I write a value to an address and "STUFF" happens independantly of the software. This is perhaps one of the key concepts for embedded programming, how to make the computer effect a change in the real world.
EDIT:
If you actually want to get a cheap board, the current trend from Micro developers is to put a dev kit on a usb thumb stick. This page has info on several, ranging from 8 bits upto ARM architectures: http://dev.emcelettronica.com/microcontrollers-usb-stick-tool
The Cypress PSOC was one of the first to do this with the "FirstTouch Starter Kit." The PSOC is a very unique part in that it has a micro controller and "Configurable analog and digital blocks" that allow you to plop down a ADC, serial port, or digital I/O using a gui and automatically configures you're C app to use it. The PSOCs also are avaliable in DIP packages which makes them easy to use on a prototyper's breadboard.
Picture your embedded controller sitting in a switched-off circuit...
The Vcc power is applied and the reset circuit asserts reset signal.
Clocks have reached running speeds and voltages stabilized, so reset is de-asserted.
Now your controller sets its instruction pointer to the "reset vector," which is physical address 0xE0000000 on this particular chip. The controller fetches the instruction at that location.
Interrupts are disabled, and the first order of business is to initialize registers such as the stack pointer. On some chips, there are flags bits (e.g., x86 direction flag) which need to be cleared or set.
Once the registers and flag bits are set up correctly, it becomes possible for interrupt service routines to run. By now, we must have run code to about location 0xE0000072 when we get to the code which enables interrupts by first toggling some GPIO pins to the external interrupt controller, then enables the CPU interrupts mask.
At this point, the equivalent of "device drivers" are running in the form of interrupt service routines. Assuming the C environment has a library which matches the interfaces of these routines' data structures, by now our boot-loader code can jump to the main() function of some C object code.
In other words, the code which brought us from power-on to main(), and which handles the low-level I/O, is written in the assembler peculiar to the chip you choose. This means that if you want to be versatile at embedded programming, you must know how to implement assembly code starting at the reset vector.
The reality is that hobbyist embedded programming doesn't allow time for implementing all the ISRs and the boot-loader code. For this reason, many people use standard software frameworks available for specific chips. Others use custom-language chips such as the BASICstamp. The BASICstamp is an embedded chip which hosts a BASIC language interpreter on-board. The interpreter and all the ISRs are pre-written for you. The BASIC environment gives you the ability to control I/O pins, read voltages, everything you could do from assembly with an embedded controller, but a bit slower.
As for the language, C is probably the most important language to know. From Java you should be able to adapt, but just remember that a lot of high level Java will not be available to you. Loads of textbooks out there but I'd recommend the original C programming book by Kernighan and Ritchie http://en.wikipedia.org/wiki/The_C_Programming_Language_(book)
For a good introduction to embedded C you could try a book by Michael J Pont:
http://www.amazon.com/Embedded-C-Michael-J-Pont/dp/020179523X
As for the embedded side of things you could start with Microchip, the IDE is OK to develop in with a reasonable simulator, and the c compilers are free for the slightly limited student editions c18 and c30 compilers, the IDE installer will also ask if you want to install a 3rd party HI-TECH C compiler which you could use. As for the processor I'd recommend selecting a standard 18 series PIC such as the PIC18F4520.
http://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1406&dDocName=en019469&part=SW007002
Whatever the chip manufacturer, you have to get to know the datasheets. You don't have to learn it all at once but will need it to hand!
Embedded, like most programming, tends to revolve around:
1) initialising a resource, in this case rather than data being from a data store it is from computer registers. Just include the processor header file (.h) and it will allow you to access these as ports (usually bytes) or pins (bits). Also micro-processors come with useful resources on the chip such as timers, analogue to digital converters (ADCs) and serial communications systems (UARTs). Remember that the chip itself is a resource and needs initialising before anything else.
2) using the resource. C will allow you to make data as global as possible and everything can access everything at every time! Avoid this temptation and keep it modular like Java will have encouraged you to (though for speed you may need to be a little looser on these rules).
But they do have an extra weapon called interrupts which can be used to provide real-time behaviour. These can be thought of a bit like OnClick() events. Interrupts can be generated by external events (e.g. buttons or receiving a byte from another device) and internal (timers, transmissions completed, ADC conversions completed). Keep interrupt service routines (ISRs) short and sweet, use them to handle real-time events (e.g. take a byte received and store it in a buffer then raise a flag) but allow background code to deal with it (e.g. check a received byte flag, if set then read the byte received). And remember the all important volatile for variables used by ISR routines and background routines!
Anyway, read around, I recommend www.ganssle.com for advice in general.
Good luck!
The scope of embedded computing has grown very broad, so the answers somewhat depend on what kind of device you're aiming at. On one end, there are 8-bit controllers with only a few KB of memory, usually programmed entirely in assembly or C. On the other end, processors such as those in your router are fairly powerful (200 MHz and a few MB of RAM is not uncommon) and often run an OS like Linux, which means you can use pretty much any language, though C and Java are the most common.
It's best to buy a real chip and experiment. Most of the work involved is usually in getting to know a device and how to interface with it, so using a simulator kind of defeats the purpose.
What's a good language to wrap my head around embedded, without investing too much time leaning an embedded-specific language?
As everyone will suggest: C. Now depending on how deep are you going to dig into your platform of choice, you may also need some assembly, but don't be scared about that: typically you'll use just a little.
If you are learning C, my personal suggestion is: work as you would do in assembly; the programming language won't give you much abstractions, so think in terms of memory management. When you've learnt how to do it move up towards abstractions and live happy.
C++ is also popular on embedded platforms, but IMHO is difficult unless you know well how to program in C you can also understand what's under the hood of its abstraction.
When you feel confident with C/C++ you can start to mess with embedded operating systems. You'll notice that they can be totally different from your OS of choice (By example not all operating systems have a C standard library, processes and splitting between userspace and kernelspace).
You'll learn how to build a cross compiler, how to mess with linker scripts, the tricks of binary formats and a lot of cool stuff.
For the theoretical point of view there's a lot of stuff as well: if you study Computer Science you can get a master's degree in embedded systems.
Can learning be done without needing to buy chips, etc. via simulators or such?
Yes: many operating systems can be run on simulators like qemu.
Can someone recommend a simplified roadmap to show how one would get sarted? I'm a little unsure where to even start.
Try to get a simple operating system which can be run on emulators, hack it and follow your curiosity. Don't be scared of messing with knotty code.
1) Most of the time for most and usually the lower end embedded system, you need to know C.
And I will still recommend you to get a vanilla development board to get yourself familiar with the work flow and tricky part of working with embedded system like debugging and cross compiling. You will run into trouble if you only rely on emulator.
You can try out The Linux Stamp, it is not expensive and is good for beginner but you do need some prior knowledge on Linux.
2) For high end embedded system, a good example is Smartphone from HTC (CPU speed can reach 1Ghz)or some other Android phone it run fast and you can even code Java on it.
C and the assembly specific to your chip.
No, you really need a real chip. Simulators aren't the real thing. You need to be able to deal with keypress jitter, voltage funkyness, etc.
The Arduino is the current fad for embedded hobbyists. I'm not a big fan of Harvard architecture, personally. But you will find oodles of help out there for it. I use an XCore for my thesis work and I have found it super easy to program multicore stuff. I would suggest starting with an AVR32 and going from there.
As everyone else is saying, you need to know C.
Have a look at AVR butterfly for a cheap development board.
Smileymicros have a simple kit with dev board and book:
http://www.smileymicros.com/index.php?module=pagemaster&PAGE_user_op=view_page&PAGE_id=41
The soon to ship Raspberry Pi board looks like an incredibly cheap way to get into this field.
Yup, Arduino would be the way to go. Agreed.. Cheap (about $20 to start) and has great API to get started with high level functions. C is a must though, can't avoid it. But if you can program in other languages you'll be all good.
My recommendation is to start shopping at http://www.sparkfun.com lots of examples to work from and helpful hints of what devices to buy.
I'm investigating using nvidia GPUs for Monte-Carlo simulations. However, I would like to use the gsl random number generators and also a parallel random number generator such as SPRNG. Does anyone know if this is possible?
Update
I've played about with RNG using GPUs. At present there isn't a nice solution. The Mersenne Twister that comes with the SDK isn't really suitable for (my) Monte-Carlo simulations since it takes an incredibly long time to generate seeds.
The NAG libraries are more promising. You can generate RNs either in batches or in individual threads. However, only a few distributions are currently supported - Uniform, exponential and Normal.
The GSL manual recommends the Mersenne Twister.
The Mersenne Twister authors have a version for Nvidia GPUs. I looked into porting this to the R package gputools but found that I needed excessively large number of draws (millions, I think) before the combination of 'generate of GPU and make available to R' was faster than just drawing in R (using only the CPU).
It really is a computation / communication tradeoff.
My colleagues and I have a preprint, to appear in the SC11 conference that revisits an alternative technique for generating random numbers that is well-suited to GPUs. The idea is that the nth random number is:
x_n = f(n)
In contrast to the conventional approach where
x_n = f(x_{n-1})
Source code is available, which implements several different generators. offering 2^64 or more streams, each with periods of 2^128 or more. All pass a wide assortment of tests (the TestU01 Crush and BigCrush suites) of both intra-stream and inter-stream statistical independence. The library also includes adapters that allow you to use our generators in a GSL framework.
Massive parallel random generation as you need it for GPUs is a difficult problem. This is an active research topic. You really have to be careful not only to have a good sequential random generator (these you find in the literature) but something that guarantees that they are independent. Pairwise independence is not sufficient for a good Monte Carlo simulation. AFAIK there is no good public domain code available.
I've just found that NAG provide some RNG routines. These libraries are free for academics.
Use the Mersenne Twister PRNG, as provided in the CUDA SDK.
Here we use sobol sequences on the GPUs.
You will have to implement them by yourself.
(If your lazy see bottom for TL;DR)
Hello, I am planning to build a new (prototype) project dealing with physical computing. Basically, I have wires. These wires all need to have their voltage read at the same time. More than a few hundred microseconds difference between the readings of each wire will completely screw it up. The Arduino takes about 114 microseconds. So the most I could read is 2 or 3 wires before the latency would skew the accuracy of the readings.
So my plan is to have an Arduino as the "master" of an array of ATTinys. The arduino is pretty cramped for space, but it's a massive playground compared to the tinys. An ATTiny13A has 1k of flash ROM(program space), 64 bytes of RAM, and 64 bytes of (not-durable and slow) EEPROM. (I'm choosing this for price as well as size)
The ATTinys in my system will not do much. Basically, all they will do is wait for a signal from the Master, and then read the voltage of 1 or 2 wires and store it in RAM(or possibly EEPROM if it's that cramped). And then send it to the Master using only 1 wire for data.(no room for more than that!).
So far then, all I should have to do is implement trivial voltage reading code (using built in ADC). But this communication bit I'm worried about. Do you think a communication protocol(using just 1 wire!) could even be implemented in such constraints?
TL;DR: In less than 1k of program space and 64 bytes of RAM(and 64 bytes of EEPROM) do you think it is possible to implement a 1 wire communication protocol? Would I need to drop to assembly to make it fit?
I know that currently my Arduino programs linking to the Wiring library are over 8k, so I'm a bit concerned.
Since you only need to send data (which is simpler than receiving) and you can select your own protocol, it should not be a problem to fit the code in the available memory space.
I once created software for an industrial control panel that contained 8x14 segment LCD display, some LEDs, some buttons, a serial (I2C) EEPROM, and serial interface to the host. A 4 bit processor was used. The device did not have any serial interface, so both the RS232C interface and I2C bus had to be implemented in software. On top of that, there was Modbus protocol (which among other things requires CRC calculations some exact timing), and the application program.
The device had some 128 x 4 bits of RAM and 1kW, 2kW, 3kW or 4kW of ROM (10 bits per word). The size of the final program was about 1100 words, so it did not quite fit in the smallest device. I used Assembler, of course.
However, instead of using multiple microcontrollers, you could consider using a hardware solution.
You could use a sample and hold circuit. For that, you need an array of analog switches and capacitors and perhaps op-amps. Just issue a trigger to latch all the voltages into the capacitors. Then you can use as much time as you need to read the voltages with your master processor.
Update: Forgot to mention that there are ready-made sample-and-hold amplifiers that need very little or no external components. This is probably the easiest solution.
1k of program space should be plenty, considering that your protocol only needs to be complicated enough to send a single integer when tickled. Look into Manchester Encoding.
You can probably get away with using a C compiler that targets this architecture, but you'll have to create your own runtime environment and not rely on the one supplied with the compiler. That's doable, but I'm not sure if the additional work to essentially create your own mini-OS outweighs the productivity benefit of using C over assembler.
I've done embedded programming in similar constraints. I used Borland Turbo C (it was a long time ago) in the tiny model and obtained code that was hardly bulkier than I could have done in assembler, with a fraction of the effort. What I'm saying is: It's quite feasible and sensible to use C as a high level assembler.
Just like me, though, you will be facing the problem of providing C with a (tiny) runtime environment. Ideally, you will only need to set up the stack and a few registers. Also, you won't have room for the C library, so you will need to program any needed functions yourself.
Yes, probably, though if you know your compiler very well you might be able to get away with c.
What you could do, is use a compiler to emit any standalone functions you need based on c code, then glue them together with a little of your own. (You'll certainly have to do the c runtime setup yourself - stacks etc.)
You may consider upgrading to the ATTiny25. It is a more capable 8-pin AVR that includes Atmel's Universal Serial Interface. It is capable of doing 1-wire serial comms in hardware, given only a few bytes of software.
Why wouldn't you just use sample-and-hold hardware, rather than a pile of microcontrollers?
I designed a master-slave system recently using an AT90USB646 master and ATtiny85 slaves. Obviously I had a lot more memory to work with on the slaves, but what I wanted to share with you is this:
With regard to your communication protocol, bear in mind that the uncalibrated internal oscillator on the ATtiny13 has an accuracy of +/- 10%. This means you won't be able to use, e.g., RS-232 communications.
I used a variant of the Dallas 1-Wire protocol in my system. Including full support for slave enumeration etc., the C source code compiles into 1626 bytes.
Edit: Whoops, didn't realize the question is so old. Hopefully this may still be of some help.