// Test that dynamically allocated TLS space is included in the root set. // RUN: LSAN_BASE="report_objects=1:use_stacks=0:use_registers=0" // RUN: %clangxx %s -DBUILD_DSO -fPIC -shared -o %t-so.so // RUN: %clangxx_lsan %s -o %t // RUN: LSAN_OPTIONS=$LSAN_BASE:"use_tls=0" not %run %t 2>&1 | FileCheck %s // RUN: LSAN_OPTIONS=$LSAN_BASE:"use_tls=1" %run %t 2>&1 // RUN: LSAN_OPTIONS="" %run %t 2>&1 #ifndef BUILD_DSO #include <assert.h> #include <dlfcn.h> #include <stdio.h> #include <stdlib.h> #include <string> int main(int argc, char *argv[]) { std::string path = std::string(argv[0]) + "-so.so"; void *handle = dlopen(path.c_str(), RTLD_LAZY); assert(handle != 0); typedef void **(* store_t)(void *p); store_t StoreToTLS = (store_t)dlsym(handle, "StoreToTLS"); assert(dlerror() == 0); void *p = malloc(1337); // If we don't know about dynamic TLS, we will return a false leak above. void **p_in_tls = StoreToTLS(p); assert(*p_in_tls == p); fprintf(stderr, "Test alloc: %p.\n", p); return 0; } // CHECK: Test alloc: [[ADDR:.*]]. // CHECK: LeakSanitizer: detected memory leaks // CHECK: [[ADDR]] (1337 bytes) // CHECK: SUMMARY: {{(Leak|Address)}}Sanitizer: #else // BUILD_DSO // A loadable module with a large thread local section, which would require // allocation of a new TLS storage chunk when loaded with dlopen(). We use it // to test the reachability of such chunks in LSan tests. // This must be large enough that it doesn't fit into preallocated static TLS // space (see STATIC_TLS_SURPLUS in glibc). __thread void *huge_thread_local_array[(1 << 20) / sizeof(void *)]; // NOLINT extern "C" void **StoreToTLS(void *p) { huge_thread_local_array[0] = p; return &huge_thread_local_array[0]; } #endif // BUILD_DSO