/* malloc_wrapper.cc This file is part of Cygwin. This software is a copyrighted work licensed under the terms of the Cygwin license. Please consult the file "CYGWIN_LICENSE" for details. */ #include "winsup.h" #include "cygerrno.h" #include "security.h" #include "path.h" #include "fhandler.h" #include "dtable.h" #include "perprocess.h" #include "miscfuncs.h" #include "cygmalloc.h" #include extern "C" struct mallinfo dlmallinfo (); /* we provide these stubs to call into a user's provided malloc if there is one - otherwise functions we provide - like strdup will cause problems if malloced on our heap and free'd on theirs. */ static bool use_internal = true; static bool internal_malloc_determined; /* Helper function to generate the correct caller address. For external calls, the return address on the stack is _sigbe. In that case the actual caller return address is on the cygtls stack. Use this function via the macro caller_return_address. */ extern "C" void _sigbe (); static inline void * __caller_return_address (void *builtin_ret_addr) { return builtin_ret_addr == &_sigbe ? (void *) _my_tls.retaddr () : builtin_ret_addr; } #define caller_return_address() \ __caller_return_address (__builtin_return_address (0)) void * __caller_return_address (void *); /* Return an address from the import jmp table of main program. */ static inline void * import_address (void *imp) { __try { if (*((uint16_t *) imp) == 0x25ff) { const char *ptr = (const char *) imp; const uintptr_t *jmpto = (uintptr_t *) (ptr + 6 + *(int32_t *)(ptr + 2)); return (void *) *jmpto; } } __except (NO_ERROR) {} __endtry return NULL; } /* These routines are used by the application if it doesn't provide its own malloc. */ extern "C" void free (void *p) { malloc_printf ("(%p), called by %p", p, caller_return_address ()); if (!use_internal) user_data->free (p); else { __malloc_lock (); dlfree (p); __malloc_unlock (); } } extern "C" void * malloc (size_t size) { void *res; if (!use_internal) res = user_data->malloc (size); else { __malloc_lock (); res = dlmalloc (size); __malloc_unlock (); } malloc_printf ("(%ld) = %p, called by %p", size, res, caller_return_address ()); return res; } extern "C" void * realloc (void *p, size_t size) { void *res; if (!use_internal) res = user_data->realloc (p, size); else { __malloc_lock (); res = dlrealloc (p, size); __malloc_unlock (); } malloc_printf ("(%p, %ld) = %p, called by %p", p, size, res, caller_return_address ()); return res; } /* BSD extension: Same as realloc, just if it fails to allocate new memory, it frees the incoming pointer. */ extern "C" void * reallocf (void *p, size_t size) { void *res = realloc (p, size); if (!res && p) free (p); return res; } extern "C" void * calloc (size_t nmemb, size_t size) { void *res; if (!use_internal) res = user_data->calloc (nmemb, size); else { __malloc_lock (); res = dlcalloc (nmemb, size); __malloc_unlock (); } malloc_printf ("(%ld, %ld) = %p, called by %p", nmemb, size, res, caller_return_address ()); return res; } extern "C" int posix_memalign (void **memptr, size_t alignment, size_t bytes) { save_errno save; void *res; if (!use_internal) return user_data->posix_memalign (memptr, alignment, bytes); if ((alignment & (alignment - 1)) != 0) return EINVAL; __malloc_lock (); res = dlmemalign (alignment, bytes); __malloc_unlock (); if (!res) return ENOMEM; *memptr = res; return 0; } extern "C" void * memalign (size_t alignment, size_t bytes) { void *res; if (!use_internal) { set_errno (ENOSYS); res = NULL; } else { __malloc_lock (); res = dlmemalign (alignment, bytes); __malloc_unlock (); } return res; } extern "C" void * valloc (size_t bytes) { void *res; if (!use_internal) { set_errno (ENOSYS); res = NULL; } else { __malloc_lock (); res = dlvalloc (bytes); __malloc_unlock (); } return res; } extern "C" size_t malloc_usable_size (void *p) { size_t res; if (!use_internal) { set_errno (ENOSYS); res = 0; } else { __malloc_lock (); res = dlmalloc_usable_size (p); __malloc_unlock (); } return res; } extern "C" int malloc_trim (size_t pad) { size_t res; if (!use_internal) { set_errno (ENOSYS); res = 0; } else { __malloc_lock (); res = dlmalloc_trim (pad); __malloc_unlock (); } return res; } extern "C" int mallopt (int p, int v) { int res; if (!use_internal) { set_errno (ENOSYS); res = 0; } else { __malloc_lock (); res = dlmallopt (p, v); __malloc_unlock (); } return res; } extern "C" void malloc_stats () { if (!use_internal) set_errno (ENOSYS); else { __malloc_lock (); dlmalloc_stats (); __malloc_unlock (); } } extern "C" struct mallinfo mallinfo () { struct mallinfo m; if (!use_internal) { memset (&m, 0, sizeof m); set_errno (ENOSYS); } else { __malloc_lock (); m = dlmallinfo (); __malloc_unlock (); } return m; } extern "C" char * strdup (const char *s) { char *p; size_t len = strlen (s) + 1; if ((p = (char *) malloc (len)) != NULL) memcpy (p, s, len); return p; } /* We use a critical section to lock access to the malloc data structures. This permits malloc to be called from different threads. Note that it does not make malloc reentrant, and it does not permit a signal handler to call malloc. The malloc code in newlib will call __malloc_lock and __malloc_unlock at appropriate times. */ SRWLOCK NO_COPY mallock = SRWLOCK_INIT; void malloc_init () { /* Check if malloc is provided by application. If so, redirect all calls to malloc/free/realloc to application provided. This may happen if some other dll calls cygwin's malloc, but main code provides its own malloc */ if (!internal_malloc_determined) { extern void *_sigfe_malloc; /* Decide if we are using our own version of malloc by testing the import address from user_data. */ use_internal = user_data->malloc == malloc || import_address ((void *) user_data->malloc) == &_sigfe_malloc; malloc_printf ("using %s malloc", use_internal ? "internal" : "external"); internal_malloc_determined = true; } } extern "C" void __set_ENOMEM () { set_errno (ENOMEM); }