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I'm programming a design for a microprocessor with very limited memory and I must use "a lot" of memory in different functions. I can't have a large stack segment, heap segment, data segment, I must choose which to make big and which to make small. I have about 32KB total,

I use about 20KB for the text segment, that gives me 12KB for the rest. And I need a buffer of 4KB to pass to different functions (SPI Flash sector size). Where should initialize that large buffer?

So my choices are:

1) If I declare the buffer at the beginning of the function, the stack would need to be made large

spiflash_read(...)
{
  u8 buffer[4096]; // allocated on stack 
  syscall_read_spi(buffer,...)
}

2) Allocate dynamically, the heap will need to be made large

spiflash_read(...)
{
  u8 *buffer = (u8*) malloc(4096); // allocated in heap
  syscall_read_spi(buffer,...)
}

3) Allocate statically, huge down side it can't be used outside the "SPI Library".

static u8 buffer[4096]; // allocated in data section.

spiflash_read(...)
{
  syscall_read_spi(buffer,...)
}

My question is which is the best way to implement this design? Can someone please explain the reasoning?

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Why do you need a 4kB buffer for reading from flash? I've worked on many systems with similar amounts of memory, but I have never needed to work on single buffers that big. You could probably design your code to not require passing around an entire flash sector. –  TJD Mar 14 '12 at 20:38
    
The "text" segment comprises code and constant data, on such a constrained system you's normally execute from read-only memory. Is there a reason why you have 20K of RAM for this purpose? –  Clifford Mar 14 '12 at 20:46
    
@TJD I am using a flash with a subsector of 4kB, you cannot erase anything less, also note you cannot write to a location that wasn't previously erased. So if I do a write I must read 4kB, modify the part I intend write to, erase the entire sector then write the 4kB back. –  user968102 Mar 14 '12 at 21:44
    
@Clifford That is besides the point of the question, but since you are interested the reason is that I am using an FPGA, around 32kB of "FPGA blockram" is what I have total to work with, given that the FPGA has limited blockrams and most of it is being used for FIFOs etc.. –  user968102 Mar 14 '12 at 21:50
    
Also, given the program logic see if you can use unions to minimize unused space. –  Alexey Frunze Mar 15 '12 at 1:54

4 Answers 4

up vote 9 down vote accepted

Static allocation is always run-time safe since if you have run out of memory, your linker will tell you at buid time rather than the code crashing at run-time. However, unless the memory is required permanently during execution, it can be wasteful, since the allocated memory cannot be re-used for multiple purposes unless you explicitly code it that way.

Dynamic memory allocation is run-time checkable - if you run out of heap, malloc() returns a null pointer. It is however beholden upon you to test the return value, and to release memory as necessary. Dynamic memory blocks are typically 4 or 8 byte aligned and carry a heap management data overhead that make them inefficient for very small allocations. Also frequent allocation and deallocation of widely varying block sizes can lead to heap fragmentation and wasted memory - it can be disastrous for "always-on" applications. If you never intend to release the memory, and it will always be allocated, and you know apriori how much you need, then you may be better off with static allocation. If you have the library source, you could modify malloc to immediatly halt on memory allocation failure to avoid having to check every allocation. If the allocations sizes are typically of a few common sizes, a fixed-block allocator rather then the standard malloc() might be preferable. It would be more deterministic, and you could implement usage monitoring to aid optimisation of block sizes and numbers of each size.

Stack allocation is the most efficient as it automatically gets and returns memory as necessary. However it also has little or no run-time checking support. Typically when a stack overflow occurs, the code will fail non-deterministically - and not necessarily anywhere near the root cause. Some linkers can generate stack analysis output that will calculate worst-case stack usage through the call tree; you should use this if you have that facility, but remember that if you have a multithreaded system, there will be multiple stacks, and you need ot check the worst case for the entry point to each. Also the lonker will not analyse interrupt stack usage, and your system may have a separate interrupt stack, or share the system stack.

The way I would tackle this is certainly not to place large arrays or objects on the stack but follow the following process:

  1. Use the linker stack analysis to calculate worst case stack usage, allow additional stack for ISRs if necessary. Allocate that much stack.

  2. Allocate all objects required for the duration of execution statically.

  3. Use the link map to determine how much memory remains, allocate almost all of that to the heap (your linker or linker script may do that automatically, but if you have to set the heap size explicitly, leave a little unused, otherwise every time you add a new static object, or extend the stack you will have to resize the heap). Allocate all large temporary objects from the heap, and be vigilent about freeing the memory allocated.

If your library includes heap diagnostic functions, you might use them within your code to monitor heap usage to check how close you are to exhaustion.

The linker analysis "worst-case" is likley to be larger that waht you see in practice - the worst case paths my never be executed. You could pre-fill teh stack with a specific byte (say 0xEE) or pattern, then after extensive testing and operation, check for the "high-tide" mark and optimise the stack that way. Use this technique with caution; your testing may not cover all forseeable circumstances.

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2  
Also beware of any static analysis that tells you "worst case" stack usage. In reality, worst case stack usage is impossible to determine via static analysis. If you use function pointers that vary dynamically, then you can't have accurate analysis of function call chains. –  TJD Mar 14 '12 at 22:09
    
@TJD: Good point. There are a number of areas where static analysis can give the wrong answer. As I said ISRs need to be considered, function pointers as TJD says, and if using an RTOS, you need to consider the worst case for each task entry point and then add the RTOS thread context overhead if that is stored on the stack - the static analysis will not account for that. Do not pare down to exactly what the static analysis says - I usually add a 20% margin or more if I can afford it. This allows headroom for code changes, so you do not have to do the analysis every time. –  Clifford Mar 15 '12 at 11:52
    
@TJD: If a properly-written static analysis which is told about "hidden" call paths (such as interrupts) is able to report a worst-case value, the actual stack requirement should be no more than that. The weakness with static analysis tools is that they may report worst-case stack usage based upon execution paths that may never occur, or may be unable to determine worst-case stack usage because the call graph contains an apparent cycle, whether or not it's possible for execution to proceed all the way around it. –  supercat Jul 9 '13 at 22:37

it depends on whether or not you need to buffer all the time. If 90% of your work is spent working on that buffer then I would put it in data segment

If it is just needed transiently for a given function then put it on the stack. This is cheap to do and means you can reuse the space. It means that you must have a large stack tho

Otherwise put it on the heap.

Really if you are this memory constrained you should do a detailed analysis of what your memory consumption is. Once you get so small you cannot treat this like 'normal', throw it at the OS/runtime, development. I have seen embedded dev shops that are not allowed to do any dynamic mem allocation; every thing is pre-calculated and allocated statically. Although they might have multi-purpose memory areas (a common IO buffer for example). Back in my COBOL days that was the only way you could work (youngsters today..., grumble, grumble....)

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The traditional answer is that you should rig your runtime so your stack and your heap grow toward each other. This allows you to ignore which one needs to be "bigger" and just worry about what happens if you didn't allocate enough space TOTAL.

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I agree. Some further observations.... Allocating it as a static has the downside he mentioned in his question. Allocating it via malloc has some overhead; granted, it's a very small amount of memory, but in a memory-constrained environment every byte counts. So that leaves allocating it on the stack as the best choice. –  Carey Gregory Mar 14 '12 at 20:08
    
Unless, of course, the heap becomes fragmented and you may still have enough free memory, but not in big enough pieces. –  Alexey Frunze Mar 15 '12 at 1:53
    
@Alex, heap fragmentation seems unlikely, given that the guy said he was on a microcontroller with extremely limited memory. As such, he's probably going to be very careful about thrashing his heap. –  John R. Strohm Mar 15 '12 at 15:45
    
@CareyGregory: If you only need to release memory objects in the reverse order of allocation, malloc() need not have any per-object overhead. Simply keep a top-of-allocated memory pointer, and have free() set that pointer to its argument. –  supercat Jul 9 '13 at 22:39

The question is, do you really need to read 4096 bytes at once?

If your data objects are smaller you can read only the necessary size.

And even if you can only erase 4kb pages, there is no need to cache the complete block in RAM, as it's a bad idea to cache it, erase and then rewrite it.

Normally, if the first page is full, you can copy necessary data to a new page in small chunks and if the second page is full you erase the first one again.

This is also safe againt power down while one of the actions is running.

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