I'm trying to disable dynamic memory allocation altogether in a low-resource application. I don't ever use malloc/free etc and as far as I can tell neither do any of my dependencies.

I've tried zero-ing out the heap in the linker file LinkerScript.ld:

_Min_Heap_Size = 0x000;  /* required amount of heap  */

But that does not seem to be a guarantee that no library function will try to call malloc.

Is there a way to enforce that no dynamic memory allocation can take place and fail the build if so?

There is NO operating system on this project (bare-metal, STM32F302R8) cross-compiled with arm-none-eabi-gcc.

  • On which operating system or, as the standard says, which runtime environment ? Mar 15 '19 at 6:07
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    You should at least edit your question to explain a lot more about your application? Is it hosted or freestanding? What C standard library, what operating system (if any) are you using? What is your application concretely doing? Why do you need to disable heap allocation? Without any such details, your question is unclear Mar 15 '19 at 6:56
  • @BasileStarynkevitch the use of gcc and stm32 tags strongly indicates a certain runtime environment which is strictly speaking freestanding, but lets the user have about as much hosted functionality as he wants. Mar 15 '19 at 10:23

In the most common gcc based Cortex-M toolchain, library functions are provided by the newlib C library. The newlib implementation of malloc() and friends allocate memory for the heap using the _sbrk() function, which has to be implemented by the user software.

If there is no _sbrk() in your application, then the build will fail at the linking. Find it and remove it.

You might also want to check out how to find out why a symbol is referenced, or make the build fail when an arbitrary library function is referenced


I'm trying to disable dynamic memory allocation altogether in a low-resource application.

This is unusual. In general people are limiting the dynamic memory used by their (hosted) application (and how to do that is a different question, often operating system specific). Why do you want to disable it entirely ? As explained below, dynamic memory is very likely to be used internally inside your C standard library implementation.

Read carefully the C11 standard n1570 (or the C99 one).

There are basically two "modes" or two "dialects" of C: the hosted C language and the freestanding C language. The exact wording in the §4 Conformance of the standard is

The two forms of conforming implementation are hosted and freestanding. A conforming hosted implementation shall accept any strictly conforming program. A conforming freestanding implementation shall accept any strictly conforming program in which the use of the features specified in the library clause (clause 7) is confined to the contents of the standard headers <float.h>, <iso646.h>, <limits.h>, <stdalign.h>, <stdarg.h>, <stdbool.h>, <stddef.h>, <stdint.h>, and <stdnoreturn.h>.

And malloc is defined (declared in <stdlib.h>) and should be available for hosted implementations and is usually not available in freestanding implementations (but that is implementation specific).

Apparently, you are using a freestanding implementation (since you don't have malloc that the standard requires from hosted implementations). GCC has the -ffreestanding mode for that. You should use it. Then <stdlib.h> is not available, and your code cannot use the standard malloc in that mode (unless it explicitly declares malloc).

In a hosted implementation, you usually can redefine your malloc (provided it still has all the properties required by the standard). Then you might use something like this (an always failing, but still standard conforming, malloc implementation).

At last, if you use a GNU binutils linker, you can always fail the link if your object files contain any external reference to malloc. That is trivial to implement -by adding some specific recipe or rule- in your Makefile (probably using nm), or if using any decent build automation tool (if your build automation don't permit such a check just before linking, switch to one that does: make, ninja, omake and many others....).

If you want to detect any use of malloc at compile time in a hosted environment, you might write your own GCC plugin doing so (I feel that is overkill, but the choice is yours). Or (much more simple in practice) use some script (e.g. with grep) detecting occurrences of the malloc or calloc word in your C source code.

Notice that in most hosted implementations, in practice standard functions like fprintf, fopen, printf, fputc (and many others) are internally -at least sometimes- using malloc. Concretely, if your program (above a hosted implementation) uses fopen it is very likely to indirectly use malloc, since inside a standard FILE there is generally some heap-allocated buffer that fopen is malloc-ing (and it usually gets free-d at fclose time).

Is there a way to enforce that no dynamic memory allocation can take place and fail the build if so?

In practice, yes. Just add some script in your Makefile doing such a check. Either use grep on your source files, or use nm on your object files. But if you use the standard fopen (from <stdio.h>) in your code, it is usually doing some malloc internally.

Alternatively, define your own always failing malloc and calloc and trivial free (like here)

On many operating systems (the one used by your application, if any), there is a way to limit the heap memory at runtime. Linux has setrlimit(2) with RLIMIT_DATA.

If you are using some free software or open-source C standard library implementation (in a hosted environment) such as GNU glibc or musl-libc, you could study its source code and check that fopen uses heap memory.

  • > This is unusual. In general people are limiting the dynamic memory in baremetal ebedded is very common to not use it entirely, there are a lot of reason like memory fragmentation, easier to control resource, and generally safer code. Analyzing map file is possible to estimate max stack usage and the rest of memory is all dedicated to data, with heap usage is much more complex
    – Lesto
    Aug 5 at 9:05

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