I'm currently working on an embedded project (STM32F103RB, CooCox CoIDE v.1.7.6 with arm-none-eabi-gcc 4.8 2013q4) and I'm trying to understand how malloc() behaves in plain C when the RAM is full.

My STM32 has 20 kB = 0x5000 bytes of RAM, 0x200 are used for the stack.

#include <stdlib.h>
#include "stm32f10x.h"

struct list_el {
   char weight[1024];

typedef struct list_el item;

int main(void)
    item * curr;

    // Allocate until RAM is full
    do {
        curr = (item *)malloc(sizeof(item));
    } while (curr != NULL);

    // I know, free() is missing. The program is supposed to crash

    return 0;

I would expect malloc() to return NULL as soon as the heap is too small for allocating:

0x5000 (RAM) - 0x83C (bss) - 0x200 (stack) = 0x45C4 (heap)

So when executing the malloc() for the 18th time. One item is 1024=0x400 bytes large.

But instead the microcontroller calls the HardFault_Handler(void) after the 18th time (not even the MemManager_Handler(void)).

How can I forecast a malloc() failure? Since waiting for a NULL return doesn't seem to work.

  • I don't have any answers either, but this would suggest the C library's malloc() function has a bug.
    – abligh
    Commented Mar 15, 2014 at 10:56
  • 1
    Are you using uClibc?
    – Michael F
    Commented Mar 15, 2014 at 11:03
  • Any way to retrieve the size of the remaining memory?
    – Déjà vu
    Commented Mar 15, 2014 at 11:04
  • I think you must define your custom malloc() because you already have RAM address using that you can do it. Commented Mar 15, 2014 at 11:14
  • 1
    @BernhardSchlegel uClibc is a particular implementation of the standard C library, you could compile your C library with debug symbols and then use a debugger to step in malloc and see exactly which line causes the call to the hardfault handler. You can use GCC with different implementations of the C library, so saying you use GCC does not really say which implementation of the C library you use. We can only assume you use the default one.
    – Étienne
    Commented Mar 15, 2014 at 16:38

5 Answers 5


It does not look like malloc is doing any checks at all. The fault that you get comes from hardware detecting a write to an invalid address, which is probably coming from malloc itself.

When malloc allocates memory, it takes a chunk from its internal pool, and returns it to you. However, it needs to store some information for the free function to be able to complete deallocation. Usually, that's the actual length of the chunk. In order to save that information, malloc takes a few bytes from the beginning of the chunk itself, writes the info there, and returns you the address past the spot where it has written its own information.

For example, let's say you asked for a 10-byte chunk. malloc would grab an available 16-byte chunk, say, at addresses 0x3200..0x320F, write the length (i.e. 16) into bytes 1 and 2, and return 0x3202 back to you. Now your program can use ten bytes from 0x3202 to 0x320B. The other four bytes are available, too - if you call realloc and ask for 14 bytes, there would be no reallocation.

The crucial point comes when malloc writes the length into the chunk of memory that it is about to return to you: the address to which it writes needs to be valid. It appears that after the 18-th iteration the address of the next chunk is negative (which translates to a very large positive) so CPU traps the write, and triggers the hard fault.

In situations when the heap and the stack grow toward each other there is no reliable way to detect an out of memory while letting you use every last byte of memory, which is often a very desirable thing. malloc cannot predict how much stack you are going to use after the allocation, so it does not even try. That is why the byte counting in most cases is on you.

In general, on embedded hardware when the space is limited to a few dozen kilobytes, you avoid malloc calls in "arbitrary" places. Instead, you pre-allocate all your memory upfront using some pre-calculated limits, and parcel it out to structures that need it, and never call malloc again.

  • The last successfull allocation returns 0x20004908 - which I believe should already not be possible. The reason I'm was using structs is that I have structures read from a SD-Card with a variable size (100Byte to 2kByte).
    – Boern
    Commented Mar 15, 2014 at 12:14

Your program most likely crashes because of an illegal memory access, which is almost always an indirect (subsequent) result of a legal memory access, but one that you did not intend to perform.

For example (which is also my guess as to what's happening on your system):

Your heap most likely begins right after the stack. Now, suppose you have a stack overflow in main. Then one of the operations that you perform in main, which is naturally a legal operation as far as you're concerned, overrides the beginning of the heap with some "junk" data.

As a subsequent result, the next time that you attempt to allocate memory from the heap, the pointer to the next available chunk of memory is no longer valid, eventually leading to a memory access violation.

So to begin with, I strongly recommend that you increase the stack size from 0x200 bytes to 0x400 bytes. This is typically defined within the linker-command file, or through the IDE, in the project's linker settings.

If your project is on IAR, then you can change it in the icf file:

define symbol __ICFEDIT_size_cstack__ = 0x400

Other than that, I suggest that you add code in your HardFault_Handler, in order to reconstruct the call stack and register values prior to the crash. This might allow you to trace the runtime error and find out exactly where it happened.

In file 'startup_stm32f03xx.s', make sure that you have the following piece of code:

EXTERN  HardFault_Handler_C        ; this declaration is probably missing

__tx_vectors                       ; this declaration is probably there
    DCD     HardFault_Handler

Then, in the same file, add the following interrupt handler (where all other handlers are located):

    PUBWEAK HardFault_Handler
    TST LR, #4
    ITE EQ
    B HardFault_Handler_C

Then, in file 'stm32f03xx.c', add the following ISR:

void HardFault_Handler_C(unsigned int* hardfault_args)
    printf("R0    = 0x%.8X\r\n", hardfault_args[0]);
    printf("R1    = 0x%.8X\r\n", hardfault_args[1]);
    printf("R2    = 0x%.8X\r\n", hardfault_args[2]);
    printf("R3    = 0x%.8X\r\n", hardfault_args[3]);
    printf("R12   = 0x%.8X\r\n", hardfault_args[4]);
    printf("LR    = 0x%.8X\r\n", hardfault_args[5]);
    printf("PC    = 0x%.8X\r\n", hardfault_args[6]);
    printf("PSR   = 0x%.8X\r\n", hardfault_args[7]);
    printf("BFAR  = 0x%.8X\r\n", *(unsigned int*)0xE000ED38);
    printf("CFSR  = 0x%.8X\r\n", *(unsigned int*)0xE000ED28);
    printf("HFSR  = 0x%.8X\r\n", *(unsigned int*)0xE000ED2C);
    printf("DFSR  = 0x%.8X\r\n", *(unsigned int*)0xE000ED30);
    printf("AFSR  = 0x%.8X\r\n", *(unsigned int*)0xE000ED3C);
    printf("SHCSR = 0x%.8X\r\n", SCB->SHCSR);
    while (1)

If you can't use printf at the point in the execution when this specific Hard-Fault interrupt occurs, then save all the above data in a global buffer instead, so you can view it after reaching the while (1).

Then, refer to the 'Cortex-M Fault Exceptions and Registers' section at http://www.keil.com/appnotes/files/apnt209.pdf in order to understand the problem, or publish the output here if you want further assistance.

In addition to all of the above, make sure that the base address of the heap is defined correctly. It is possibly hard coded within the project settings (typically right after the data section and the stack). But it can also be determined during runtime, at the initialization phase of your program. In general, you need to check the base addresses of the data section and the stack of your program (in the map file created after building the project), and make sure that the heap does not overlap either one of them.

I once had a case where the base address of the heap was set to a constant address, which was fine to begin with. But then I gradually increased the size of the data-section, by adding global variables to the program. The stack was located right after the data-section, and it "moved forward" as the data section grew larger, so there were no problems with either one of them. But eventually, the heap was allocated "on top of" part of the stack. So at some point, heap operations began to override variables on the stack, and stack operations began to override the contents of the heap.

  • 2
    The phrase you are looking for is "stack--heap collision". Very rare condition on a modern, full-service OS but they used to be an issue on many platforms and are still an issue in more restricted environments. Commented Mar 15, 2014 at 17:44
  • @dmckee: Thank you for the terminology. I've experienced this problem while using ThreadX OS, which gives you the first unused memory address in a callback function (i.e., during runtime), and allows you to allocate the heap at that address. The problem occurred because I was using a constant address instead, assuming that it was "good enough". Commented Mar 15, 2014 at 17:50

The arm-none-eabi-* toolchain distribution includes the newlib C library. When newlib is configured for an embedded system, then the user program must provide an _sbrk() function for it to work properly.

malloc() relies solely on _sbrk() to figure out where the heap memory starts, and where it ends. The very first call to _sbrk() returns the start of the heap, and subsequent calls should return -1 if the required amount of memory is not available, then malloc() would in turn return NULL to the application. Your _sbrk() looks broken, because it apparently lets you allocate more memory than there is available. You should be able to fix it so that it returns -1 before the heap is expected to collide with the stack.


Using standard C malloc, it's very hard to distinguish and malloc seems buggy from my view. So you can manage memory by implementing some custom malloc using your RAM address.

I am not sure may this help you, but I have done some custom malloc in my controller-related project. It's as follows:

#define LENGTH_36_NUM    (44)
#define LENGTH_52_NUM    (26)
#define LENGTH_64_NUM    (4)
#define LENGTH_128_NUM    (5)
#define LENGTH_132_NUM    (8)
#define LENGTH_256_NUM    (8)
#define LENGTH_512_NUM    (18)
#define LENGTH_640_NUM    (8)
#define LENGTH_1536_NUM    (6)

#define CUS_MEM_USED        (1)
#define CUS_MEM_NO_USED        (0)

#define CALC_CNT    (0)
#define CALC_MAX    (1)

#define __Ram_Loc__         (0x20000000) ///This is my RAM address
#define __TOP_Ram_Loc__     (0x20000000 + 0x8000 -0x10)    //Total 32K RAM and last 16 bytes reserved for some data storage

typedef struct _CUS_MEM_BLOCK_S {
    char used;
    int block_size;
    char *ptr;
    char *next;
} cus_mem_block_s;

static struct _MEM_INFO_TBL_S {
    int block_size;
    int num_max;
    cus_mem_block_s *wm_head;
    int calc[2];
} memInfoTbl[] = {

 {36,  LENGTH_36_NUM  , 0, {0,0} },
 {52,  LENGTH_52_NUM  , 0, {0,0} },
 {64,  LENGTH_64_NUM  , 0, {0,0} },
 {128, LENGTH_128_NUM , 0, {0,0} },
 {132, LENGTH_132_NUM , 0, {0,0} },
 {256, LENGTH_256_NUM , 0, {0,0} },
 {512, LENGTH_512_NUM , 0, {0,0} },
 {640, LENGTH_640_NUM , 0, {0,0} },
 {1536,LENGTH_1536_NUM, 0, {0,0} },
#define MEM_TBL_MAX        (sizeof(memInfoTbl)/sizeof(struct _MEM_INFO_TBL_S))

BOOL MemHeapHasBeenInitialised = FALSE;

This basic macro defines for a RAM address and has to manually chose more block numbers for the block size which frequently require to allocate. Like, 36 bytes required me more, so I take more numbers for it.

This is the init function for memory init:

void cus_MemInit(void)
    int i,j;
    cus_mem_block_s *head=NULL;
    unsigned int addr;

    addr = __Ram_Loc__;

    for(i=0; i<MEM_TBL_MAX; i++)
        head = (char *)addr;
        memInfoTbl[i].wm_head = head;
        for(j=0;j<memInfoTbl[i].num_max; j++)
            head->used =CUS_MEM_NO_USED;
            head->block_size = memInfoTbl[i].block_size;
            head->ptr = (char *)(addr + sizeof(cus_mem_block_s));
            addr += (memInfoTbl[i].block_size + sizeof(cus_mem_block_s));
            head->next =(char *)addr;
            head = head->next;
            if(head > __TOP_Ram_Loc__)
    head->ptr = 0;
    head->block_size = 0;
    head->next = __Ram_Loc__;


This one is for allocation:

void* CUS_Malloc( int wantedSize )
    void *pwtReturn = NULL;
    int i;
    cus_mem_block_s *head;

    if(MemHeapHasBeenInitialised == FALSE)
            goto done_exit;

    for(i=0; i<MEM_TBL_MAX; i++)
        if(wantedSize <= memInfoTbl[i].block_size)
            head = memInfoTbl[i].wm_head;
                if(head->used == CUS_MEM_NO_USED)
                    head->used = CUS_MEM_USED;
                    pwtReturn = head->ptr;
                    goto done;
                head = head->next;
            goto done;


        for(i=0; i<MEM_TBL_MAX; i++)
            if(memInfoTbl[i].block_size == head->block_size)

                if(memInfoTbl[i].calc[CALC_CNT] > memInfoTbl[i].calc[CALC_MAX] )
    return pwtReturn;

This one is for free:

void CUS_Free(void *pm)
    cus_mem_block_s *head;
    char fault=0;

    if( (pm == NULL) || (MemHeapHasBeenInitialised == FALSE) )
        goto done;
    if( (pm < __RamAHB32__) && (pm > __TOP_Ram_Loc__) )
        printf("%s:over memory range\n",__FUNCTION__);
        goto done;

    head = pm-sizeof(cus_mem_block_s);

        head->used = CUS_MEM_NO_USED;
        printf("%s:free error\n",__FUNCTION__);

        goto done;
    int i;
        if(memInfoTbl[i].block_size == head->block_size)
            goto done;


After all, you can use the above function like:

void *mem=NULL;

Then it can also watch your used memory as follows:

void CUS_MemShow(void)
    int i;
    int block_size;
    int block_cnt[MEM_TBL_MAX];
    int usedSize=0, totalSize=0;
    cus_mem_block_s *head;

    if(MemHeapHasBeenInitialised == FALSE)

    memset(block_cnt, 0, sizeof(block_cnt));

    head = memInfoTbl[0].wm_head;
    block_size = head->block_size;
    while( head->ptr !=0)
        if(head->used == CUS_MEM_USED )
            usedSize +=head->block_size;
        usedSize += sizeof(cus_mem_block_s);

        totalSize += (head->block_size+ sizeof(cus_mem_block_s));

        /* change next memory block */
        head = head->next;
        if( block_size != head->block_size)
            block_size = head->block_size;

    usedSize += sizeof(cus_mem_block_s);
    totalSize+= sizeof(cus_mem_block_s);

    dprintf("----Memory Information----\n");

    for(i=0; i<MEM_TBL_MAX; i++) {
        printf("block %d used=%d/%d (max %d)\n",
                    memInfoTbl[i].block_size, block_cnt[i],

    printf("used memory=%d\n",usedSize);
    printf("free memory=%d\n",totalSize-usedSize);
    printf("total memory=%d\n",totalSize);

In general, have the memory pre-calculated first and then give it as I have.

  • 3
    three questions: 1. Can you explain what exactly your macro defines in the memInfoTbl[] are for? 2. I don't see where you are placing your stack. You check head against __TOP_Ram_Loc__ but shouldn't there be some bytes left? 3. whats __RamAHB32__ for?
    – Boern
    Commented Mar 15, 2014 at 15:27

Here you can find how I could "force" malloc() to return NULL, if the heap is too small for allocating based on berendi's previous answer. I estimated the maximum amount of STACK and based on this I could calculate the address where the stack can start in worst case.

#define STACK_END_ADDRESS       0x20020000
#define STACK_MAX_SIZE              0x0400

void * _sbrk_r(
   struct _reent *_s_r,
   ptrdiff_t nbytes)
   char  *base;     /*  errno should be set to  ENOMEM on error */

   if (!heap_ptr) { /*  Initialize if first time through.       */
      heap_ptr = end;
   base = heap_ptr; /*  Point to end of heap.           */
      heap_ptr += nbytes;   /*  Increase heap.              */
      return base;      /*  Return pointer to start of new heap area.   */
      /* End of heap mustn't exceed beginning of stack! */        
      if (heap_ptr <= (char *) (STACK_START_ADDRESS - nbytes) ) {  
         heap_ptr += nbytes;    /*  Increase heap.              */
         return base;       /*  Return pointer to start of new heap area.   */
      } else {
         return (void *) -1;         /*   Return -1 means that memory run out  */
  • There isn't anyone by the name "berendi" here. What answer does it refer to? Commented Apr 4 at 18:29

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