I want to write a function computeWriteSet that takes an arbitrary function f as an argument and (1) executes the function f and (2) returns the set of places modified or written to (addresses/pages/objects) during f's execution.

writeset computeWriteSet(function f) {
  writeset ws = createEmptyWriteset();
  // prepare to execute f
  // post-process the write-set
  return ws;
  1. What options exist for implementing it?
  2. What are their tradeoffs (in which case which implementation is more efficient and what are the limitations?)


The function is specified at runtime and can do anything (i.e. can contain any set of instructions, including loops, branching and function/system calls.

All writes from the time f is called until it returns should be recorded (this includes functions called from within f itself). For simplicity, let's assume computeWriteSet is not called from within.

OS-specific tricks are allowed (and probably required). I'm particularly interested in Linux, ideally within userspace.


static int x = 0;
static int y = 0;
static int z = 0;

void a() {
  if (y) z++;
  if (x) y++;
  x = (x + 1) % 2;

int main() {
  computeWriteSet(a); // returns { &x }     => {x,y,z} = {1, 0, 0}
  computeWriteSet(a); // returns { &x, &y } => {x,y,z} = {0, 1, 0}
  computeWriteSet(a); // returns { &x, &z } => {x,y,z} = {1, 1, 1}
  return 0;

Expected Output

The output should be the set of changes. This can be either the set of pages:

{ <address of x>, <address of y>, …}

Or the set of memory addresses:

{<page of x and y>, <page of z>, …}

Or the set of objects ( (based on interposition of allocation functions)

x = malloc(100) // returns address 0xAAA
y = malloc(200) // returns address 0xBBB

{ {address, size}, {0xAAA, 100}, {0xBBB, 200}, … }

The return value is loosely specified on purpose -- different techniques will have different spatial resolution and different overheads.

Please note:

This is a highly uncommon programming question, hence if you think it should be closed let me know why and, ideally, how to phrase/place it so that it follows the guidelines. :-)

  • 1
    The sourcecode of valgrind/memcheck may contain what you want.
    – Bodo
    Feb 14, 2019 at 17:46
  • 1
    I suspect the way those programs work is by using mprotect to mark the memory read-only. Then any memory modifications trigger a signal, and a handler keeps track of what memory it was trying to modify.
    – Barmar
    Feb 14, 2019 at 18:00
  • continuing @Barmar thought. After you detect the write into a read-only page, you would need to set protection to write and repeat the operation (this is what a debugger typically does when it watches writes). This would be awfully slow though.
    – Serge
    Feb 14, 2019 at 19:37
  • there is no good way for doing what you asked for. It would require instrumentation of the code, similar to valgrind, or other tools. The trade off will be run time performance and extra compilation or run steps. Also a lot of headache to develop (or reuse) this feature.
    – Serge
    Feb 14, 2019 at 19:45
  • 1
    If you are looking for tools, which can help you in your task, then your question is off-topic as "software recommendation" one. If you want to collect ideas, then the question is off-topic as "open-ended". If you want to have an answer, which completely describes a way for achieve what do you want, then such answer would be too long for Stack Overflow format. You need to reduce the scope of the question by selecting an instrumentation tool, and ask specifically about applying this tool for a specific task.
    – Tsyvarev
    Feb 14, 2019 at 20:42

1 Answer 1


As suggested by @Barmar, one way of accomplishing this is via mprotect.

This will generate one exception for each of the memory pages, which may add considerable overhead depending on the function. This exception is handled by us and we then insert the corresponding address into a set.

A small 100-line C++/C fully-contained messy program showcasing this is included below.

#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <signal.h>
#include <ucontext.h>
#include <fcntl.h>
#include <execinfo.h>
#include <sys/mman.h>

#include <set>
#include <functional>
#include <cassert>

extern "C" {
extern int __data_start;
extern int _end;

#define PAGE_SIZE sysconf(_SC_PAGESIZE)
#define PAGE_MASK (PAGE_SIZE - 1)
#define PAGE_ALIGN_DOWN(x) (((intptr_t) (x)) & ~PAGE_MASK)
#define PAGE_ALIGN_UP(x) ((((intptr_t) (x)) + PAGE_MASK) & ~PAGE_MASK)
#define GLOBALS_START PAGE_ALIGN_DOWN((intptr_t) &__data_start)
#define GLOBALS_END   PAGE_ALIGN_UP((intptr_t) &_end - 1)

std::set<void*> *addresses = new std::set<void*>();

void sighandler(int signum, siginfo_t *siginfo, void *ctx) {
    void *addr = siginfo->si_addr;
    void *aligned_addr = reinterpret_cast<void*>(PAGE_ALIGN_DOWN(addr));
    switch(siginfo->si_code) {
    case SEGV_ACCERR:
        mprotect(aligned_addr, PAGE_SIZE, PROT_READ | PROT_WRITE);

void computeWriteSet(std::function<void()> f) {
    static bool initialized = false;
    if (!initialized) {
        // install signal handler
        stack_t sigstk;
        sigstk.ss_sp = malloc(SIGSTKSZ);
        sigstk.ss_size = SIGSTKSZ;
        sigstk.ss_flags = 0;
        sigaltstack(&sigstk, NULL);
        struct sigaction siga;
        sigaddset(&siga.sa_mask, SIGSEGV);
        sigprocmask(SIG_BLOCK, &siga.sa_mask, NULL);
        siga.sa_flags = SA_SIGINFO | SA_ONSTACK | SA_RESTART | SA_NODEFER;
        siga.sa_sigaction = sighandler;
        sigaction(SIGSEGV, &siga, NULL);
        sigprocmask(SIG_UNBLOCK, &siga.sa_mask, NULL);
        initialized = true;
    printf("\nexecuting function\n");
    mprotect(reinterpret_cast<void*>(GLOBALS_START), GLOBALS_SIZE, PROT_READ);
    mprotect(reinterpret_cast<void*>(GLOBALS_START), GLOBALS_SIZE, PROT_READ | PROT_WRITE);
    printf("pages written:\n");
    for (auto addr : *addresses) {
        printf("%p\n", addr);

void f() {
    static int x[1024] = {0};
    static int y[1024] = {0};
    static int z[1024] = {0};
    static bool firsttime = true;
    if (firsttime) {
        printf("&x[0] = %p\n&y[0] = %p\n&z[0] = %p\n", x, y, z);
        firsttime = false;
    if (y[0]) z[0]++;
    if (x[0]) y[0]++;
    x[0] = (x[0] + 1) % 2;
    printf("{x, y, z} = {%d, %d, %d}\n", x[0], y[0], z[0]);

int main() {
    return 0;

Compiled using g++ --std=c++11 example.cpp.

Execution prints something like:

executing function
&x[0] = 0x6041c0
&y[0] = 0x6051c0
&z[0] = 0x6061c0
{x, y, z} = {1, 0, 0}
pages written:

executing function
{x, y, z} = {0, 1, 0}
pages written:

executing function
{x, y, z} = {1, 1, 1}
pages written:

Some notes:

  • We make x, y and z large-enough arrays (of size PAGE_SIZE/sizeof(int), which is 1024 on my machine) so that they fall in different memory pages and therefore can be differentiated.

  • This program will only work for global/static variables so that it can be short-ish. To extend it to work with heaps and other memory mappings can be done via interpositions, as suggested by @AShelly.

On-topic follow-up: Is there any way of avoiding the O(N) signals, where N is the number of pages written to?

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