/* * Copyright (c) 2009 - 2013 Monoidics ltd. * Copyright (c) 2013 - present Facebook, Inc. * All rights reserved. * * This source code is licensed under the BSD style license found in the * LICENSE file in the root directory of this source tree. An additional grant * of patent rights can be found in the PATENTS file in the same directory. */ // Basic modelling of some libc functions // prevent _FORTIFY_SOURCE from changing some function prototypes // https://securityblog.redhat.com/2014/03/26/fortify-and-you/ #ifdef _FORTIFY_SOURCE #undef _FORTIFY_SOURCE #endif #define _FORTIFY_SOURCE 0 #ifdef __APPLE__ // disable block instructions on mac #ifdef __BLOCKS__ #undef __BLOCKS__ #endif #ifdef _POSIX_C_SOURCE #undef _POSIX_C_SOURCE #endif #endif #include "infer_builtins.h" // use c++ headers if in C++ mode - they are mostly same as C headers, // but there are some subtle differences from time to time. For example, // 'getc' may be defined as macro in stdio.h, and a function in cstdio #ifdef __cplusplus #include #include #include #include #include #include #include #include #else #include #include #include #include #include #include #include #include #endif #include #include #include #include #include #include #include #include #include #include #ifdef __APPLE__ // includes for statfs are system-dependent #include #include #else #include #endif #ifndef __APPLE__ /* struct __dirstream is abstract on Linux, at least on Debian 8.0 we need it to be concrete to model closedir (5) */ /* dummy __dirstream structure */ struct __dirstream { int fd; }; #endif // this condition checks whether to use C++ const-overloads of C functions // for example strchr. #if defined(__CORRECT_ISO_CPP_STRING_H_PROTO) || \ defined(_LIBCPP_PREFERRED_OVERLOAD) #define INFER_USE_CPP_CONST_OVERLOAD #endif // modelling of errno // errno expands to different function calls on mac or other systems // the function call returns the address of a global variable called "errno" extern int errno; #ifdef __APPLE__ #define __ERRNO_FUN_NAME __error #else #define __ERRNO_FUN_NAME __errno_location #endif int* __ERRNO_FUN_NAME() { return &errno; } // the strings s1 and s2 need to be allocated // check that s2 fits inside s1 char* strcpy(char* s1, const char* s2) { int size1; int size2; __infer_set_flag("ignore_return", ""); // no warnings if the return value is ignored __require_allocated_array(s1); size1 = __get_array_length(s1); __require_allocated_array(s2); size2 = __get_array_length(s2); INFER_EXCLUDE_CONDITION(size2 > size1); return s1; } // the string s must be allocated; return the result of malloc with the same // size char* strdup(const char* s) { int size; __require_allocated_array(s); size = __get_array_length(s); return (char*)malloc(size); } // the strings s1 and s2 need to be allocated // check that s2 fits inside s1 char* strcat(char* s1, const char* s2) { int size1; int size2; __require_allocated_array(s1); size1 = __get_array_length(s1); __require_allocated_array(s2); size2 = __get_array_length(s2); INFER_EXCLUDE_CONDITION(size2 > size1); return s1; } // C++ has two versions of strchr: // http://www.cplusplus.com/reference/cstring/strchr/ // C has one version of strchr/strrchr with different signature // The string s must be allocated // nondeterministically return 0 or a pointer inside the buffer #ifndef INFER_USE_CPP_CONST_OVERLOAD char* strchr(const char* s, int c) { #else // This overload is commented out on purpose. // Standard headers define both functions with same __asm symbol which // means they cannot be both defined. On the other hand, since both of them // have same __asm symbol, mangling will be the same and infer will have // specs for both functions (they both will have the same name) // NOTE: this was tested on couple of systems, it may not be always true. // const char* strchr(const char* s, int c) throw() { return strchr((char*)s, // c); } char* strchr(char* s, int c) throw() { #endif int size; int nondet; int offset; nondet = __infer_nondet_int(); offset = __infer_nondet_int(); __require_allocated_array(s); size = __get_array_length(s); if (nondet) return 0; INFER_EXCLUDE_CONDITION(offset < 0 || offset >= size); return (char*)s + offset; } // modelled like strchr #ifndef INFER_USE_CPP_CONST_OVERLOAD char* strrchr(const char* s, int c) { return strchr(s, c); } #else // This overload is commented out on purpose. Look at strchr() for more info. /*const char* strrchr(const char* s, int c) throw() { return strchr((char*)s, c); }*/ char* strrchr(char* s, int c) throw() { return strchr(s, c); } #endif // s1 and s2 must be allocated. // return a non-deterministic integer int strcmp(const char* s1, const char* s2) { int res; res = __infer_nondet_int(); __require_allocated_array(s1); __require_allocated_array(s2); return res; } // the string s must be allocated // return the size of the buffer - 1 size_t strlen(const char* s) { int size; __require_allocated_array(s); size = __get_array_length(s); return size - 1; } // s must be allocated // return s char* strlwr(char* s) { __require_allocated_array(s); return s; } // s1 and s2 must be allocated // n should not be greater than the size of s1 or s2 // return s1 char* strncat(char* s1, const char* s2, size_t n) { int size_s1; int size_s2; __require_allocated_array(s1); size_s1 = __get_array_length(s1); __require_allocated_array(s2); size_s2 = __get_array_length(s2); INFER_EXCLUDE_CONDITION((n > size_s1) || (n > size_s2)); return s1; } // s1 and s2 must be allocated // n should not be greater than the size of s1 or s2 // return a non-deterministic integer int strncmp(const char* s1, const char* s2, size_t n) { int size_s1; int size_s2; int res; res = __infer_nondet_int(); __require_allocated_array(s1); size_s1 = __get_array_length(s1); __require_allocated_array(s2); size_s2 = __get_array_length(s2); INFER_EXCLUDE_CONDITION((n > size_s1) || (n > size_s2)); return res; } // the strings s1 and s2 need to be allocated // check that n characters fit in s1 (because even if s2 is shorter than n, null // characters are appended to s1) char* strncpy(char* s1, const char* s2, size_t n) { int size1; __infer_set_flag("ignore_return", ""); // no warnings if the return value is ignored __require_allocated_array(s1); size1 = __get_array_length(s1); __require_allocated_array(s2); INFER_EXCLUDE_CONDITION(n > size1); return s1; } #ifndef INFER_USE_CPP_CONST_OVERLOAD char* strpbrk(const char* s1, const char* s2) { #else // This overload is commented out on purpose. Look at strchr() for more info. /*const char* strpbrk(const char* s1, const char* s2) throw() { return strpbrk((char*)s1, s2); }*/ char* strpbrk(char* s1, const char* s2) throw() { #endif int size1; int nondet; int offset; nondet = __infer_nondet_int(); offset = __infer_nondet_int(); __require_allocated_array(s1); size1 = __get_array_length(s1); __require_allocated_array(s2); if (nondet) return 0; INFER_EXCLUDE_CONDITION(offset < 0 || offset >= size1); return (char*)s1 + offset; } // s1 and s2 must be allocated. // return an integer between 0 ans the size of s1 size_t strspn(const char* s1, const char* s2) { int size_s1; int res; res = __infer_nondet_int(); __require_allocated_array(s1); size_s1 = __get_array_length(s1); __require_allocated_array(s2); INFER_EXCLUDE_CONDITION(res < 0 || res > size_s1); return res; } #ifndef INFER_USE_CPP_CONST_OVERLOAD char* strstr(const char* s1, const char* s2) { #else // This overload is commented out on purpose. Look at strchr() for more info. /*const char* strstr(const char* s1, const char* s2) throw() { return strstr((char*)s1, s2); }*/ char* strstr(char* s1, const char* s2) throw() { #endif int size1, size2; int nondet; int offset; nondet = __infer_nondet_int(); offset = __infer_nondet_int(); __require_allocated_array(s1); size1 = __get_array_length(s1); __require_allocated_array(s2); if (nondet) return 0; INFER_EXCLUDE_CONDITION(offset < 0 || offset >= size1); return (char*)s1 + offset; } // modeled using strtoul double strtod(const char* str, char** endptr) { return (double)strtoul(str, endptr, 0); } // modeled like strtoul long strtol(const char* str, char** endptr, int base) { return (long)strtoul(str, endptr, base); } // the string s must be allocated // assign to endptr a pointer somewhere inside the string str // result is nondeterministic unsigned long strtoul(const char* str, char** endptr, int base) { int size; int offset; int res; __require_allocated_array(str); size = __get_array_length(str); offset = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(offset < 0 || offset >= size); if (endptr) *endptr = (char*)(str + offset); res = __infer_nondet_int(); int errno_val = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(errno_val < 0); errno = errno_val; return res; } // s must be allocated // return s char* strupr(char* s) { __require_allocated_array(s); return s; } // the array s must be allocated // n should not be greater than the size of s // nondeterministically return 0 or a pointer within the first n elements of s #ifndef INFER_USE_CPP_CONST_OVERLOAD void* memchr(const void* s, int c, size_t n) { #else // This overload is commented out on purpose. Look at strchr() for more info. // const void* memchr(const void* s, int c, size_t n) throw() { // return memchr((void*)s, c, n); //} void* memchr(void* s, int c, size_t n) throw() { #endif int size; int nondet; int offset; nondet = __infer_nondet_int(); offset = __infer_nondet_int(); __require_allocated_array(s); size = __get_array_length(s); INFER_EXCLUDE_CONDITION(n > size); if (nondet) return 0; INFER_EXCLUDE_CONDITION(offset < 0 || offset >= n); return (char*)s + offset; } // s1 and s2 must be allocated // n should not be greater than the size of s1 or s2 // return a non-deterministic integer int memcmp(const void* s1, const void* s2, size_t n) { int size_s1; int size_s2; __require_allocated_array(s1); size_s1 = __get_array_length(s1); __require_allocated_array(s2); size_s2 = __get_array_length(s2); INFER_EXCLUDE_CONDITION((n > size_s1) || (n > size_s2)); return __infer_nondet_int(); } // s1 and s2 must be allocated // n must be between 0 and the minumum of the sizes of s1 and s2 void* memcpy(void* s1, const void* s2, size_t n) { int size_s1; int size_s2; __infer_set_flag("ignore_return", ""); // no warnings if the return value is ignored __require_allocated_array(s1); size_s1 = __get_array_length(s1); __require_allocated_array(s2); size_s2 = __get_array_length(s2); INFER_EXCLUDE_CONDITION((n < 0) || (n > size_s1) || (n > size_s2)); return s1; } // modeld using memcpy void* memmove(void* s1, const void* s2, size_t n) { __infer_set_flag("ignore_return", ""); // no warnings if the return value is ignored return memcpy(s1, s2, n); } // s needs to be allocated // n should not be greater than the size of s void* memset(void* s, int c, size_t n) { int size_s; __infer_set_flag("ignore_return", ""); // no warnings if the return value is ignored __require_allocated_array(s); size_s = __get_array_length(s); INFER_EXCLUDE_CONDITION(n > size_s); return s; } // return a nondeterministic double double atof(const char* str) { return __infer_nondet_double(); } // return a nondeterministic value between INT_MIN and INT_MAX int atoi(const char* str) { int retu = INT_MAX; int retl = INT_MIN; int ret; if (__infer_nondet_int()) ret = retu; else ret = retl; return ret; } // modeled using malloc and set file attribute FILE* fopen(const char* filename, const char* mode) { FILE* ret; ret = (FILE*)malloc(sizeof(FILE)); if (ret) __set_file_attribute(ret); return ret; } // modeled using fopen FILE* tmpfile(void) { return fopen("foo", ""); } // use a global variable to model the return value of tmpnam extern char* _tmpnam_global; // return NULL, or if s is NULL return a global variable, otherwise check that s // has size at least L_tmpnam and return s char* tmpnam(char* s) { int success; int size; success = __infer_nondet_int(); if (!success) return NULL; if (s) { __require_allocated_array(s); size = __get_array_length(s); INFER_EXCLUDE_CONDITION(size < L_tmpnam); return s; } else return _tmpnam_global; } // nondeterministically return NULL or the original stream FILE* freopen(const char* __restrict filename, const char* __restrict mode, FILE* __restrict stream) { int n; n = __infer_nondet_int(); if (n) return NULL; else return stream; } // modeled using free, can return EOF int fclose(FILE* stream) { int n; free(stream); n = __infer_nondet_int(); if (n > 0) return 0; else return EOF; } // modeled using malloc and set file attribute // return the allocated ptr - 1 if malloc succeeds, otherwise return -1 int open(const char* path, int oflag, ...) { int* ret = (int*)malloc(sizeof(int)); if (ret) { __set_file_attribute(ret); INFER_EXCLUDE_CONDITION(ret < (int*)1); // force result to be > 0 return (size_t)ret; } return -1; } // modeled using free, can return -1 int close(int fildes) { int n; if (fildes != -1) free((int*)(long)fildes); n = __infer_nondet_int(); if (n > 0) return 0; else return -1; } // modeled as close followed by fopen FILE* fdopen(int fildes, const char* mode) { close(fildes); return fopen("foo", mode); } // modeled using fdopen FILE* gzdopen(int fildes, const char* mode) { return fdopen(fildes, mode); } // return nonteterministically 0 or -1 // requires stream to be allocated int fseek(FILE* stream, long int offset, int whence) { int n; FILE tmp; tmp = *stream; n = __infer_nondet_int(); if (n) return 0; else return -1; } // return nondeterministically a nonnegative value or -1 // requires stream to be allocated long int ftell(FILE* stream) { int n; FILE tmp; tmp = *stream; n = __infer_nondet_int(); if (n >= 0) return n; else return -1; } // on success return str otherwise null // requires stream to be allocated char* fgets(char* str, int num, FILE* stream) { int n; int size1; FILE tmp; tmp = *stream; n = __infer_nondet_int(); if (n > 0) { __require_allocated_array(str); size1 = __get_array_length(str); INFER_EXCLUDE_CONDITION(num > size1); return str; } else return NULL; } // string s must be allocated; return nondeterministically s or NULL char* gets(char* s) { int n; __require_allocated_array(s); n = __infer_nondet_int(); if (n) return s; else return NULL; } // str must be allocated, return a nondeterministic value int puts(const char* str) { __require_allocated_array(str); return __infer_nondet_int(); } // modeled using puts // require the stream to be allocated int fputs(const char* str, FILE* stream) { FILE tmp; tmp = *stream; return puts(str); } // return a nondeterministic value // requires stream to be allocated int getc(FILE* stream) { FILE tmp; tmp = *stream; return __infer_nondet_int(); } // return a nondeterministic value // requires stream to be allocated int fgetc(FILE* stream) { FILE tmp; tmp = *stream; return __infer_nondet_int(); } // return nondeterministically c or EOF // requires stream to be allocated int ungetc(int c, FILE* stream) { int n; FILE tmp; tmp = *stream; n = __infer_nondet_int(); if (n) return c; else return EOF; } // modeled like putc // requires stream to be allocated int fputc(int c, FILE* stream) { FILE tmp; tmp = *stream; return putc(c, stream); } // on success return buffer otherwise null char* getcwd(char* buffer, size_t size) { int n; int size_buf; n = __infer_nondet_int(); if (n > 0) { __require_allocated_array(buffer); size_buf = __get_array_length(buffer); INFER_EXCLUDE_CONDITION(size > size_buf); return buffer; } else return NULL; } // return nonteterministically 0 or -1 int rename(const char* old, const char* new_) { int n; n = __infer_nondet_int(); if (n) return 0; else return -1; } // modeled as skip // requires stream to be allocated void rewind(FILE* stream) { FILE tmp; tmp = *stream; } // modeled as exit() void longjmp(jmp_buf env, int val) { exit(0); } // modeled as skip. // If sleep() returns because the requested time has elapsed, // the value returned shall be 0. If sleep() returns due to delivery of a // signal, // the return value shall be the "unslept" amount (the requested time minus the // time actually slept) in seconds. unsigned sleep(unsigned seconds) { int n; n = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(n < 0); return n; } #ifdef __CYGWIN__ // define __WAIT_STATUS as int * on cygwin #define __WAIT_STATUS int* #endif #ifdef __APPLE__ // define __WAIT_STATUS as int * on mac #define __WAIT_STATUS int* #endif // glibc 2.24 did away with 'union wait' and replaced it with int*. // Hence, we re-define __WAIT_STATUS if glibc is >= 2.24. #ifndef __GLIBC_PREREQ #define __GLIBC_PREREQ(x, y) 0 #endif #if defined(__GLIBC__) && __GLIBC_PREREQ(2, 24) #define __WAIT_STATUS int* #endif // the waiting is modeled as skip. Then the return value is a random value of a // process or // -1 in case of an error pid_t wait(__WAIT_STATUS stat_loc) { int n; pid_t tmp; n = __infer_nondet_int(); tmp = __infer_nondet_int(); if (n > 0) return tmp; else return -1; } #ifndef __cplusplus // return a nondeterministic pointer void (*signal(int sig, void (*func)(int)))(int) { void (*res)(int) = __infer_nondet_ptr(); return res; }; #endif // modelled as exit void pthread_exit(void* value_ptr) { exit(0); }; // INTENDED SEMANTICS: The setitimer() function shall set the timer specified by // which // to the value specified in the structure pointed to by value, and if ovalue is // not a null pointer, // store the previous value of the timer in the structure pointed to by ovalue. int setitimer(int which, const struct itimerval* __restrict value, struct itimerval* __restrict ovalue) { int n; int tmp; n = __infer_nondet_int(); tmp = __infer_nondet_int(); // not sure about this assignment. // it should somehow change the value of the timer which. // But which is just an int, so it looks like this is useless which = tmp; if (n > 0) return 0; else return -1; } // pause returns only when a signal is received // the return value is always -1 int pause(void) { return -1; } // modeled with nondeterministic value n pid_t fork(void) { return __infer_nondet_int(); } // allocate memory directly, and return -1 if malloc fails. int shmget(key_t key, size_t size, int shmflg) { void* res = malloc(size); if (!res) return -1; return (long)res; } // simply return the first parameter void* shmat(int shmid, const void* shmaddr, int shmflg) { return (void*)(long)shmid; } // return a non-deterministic value int shmdt(const void* shmaddr) { return __infer_nondet_int(); } // if the command is IPC_RMID free the first parameter; return a // non-deterministic value int shmctl(int shmid, int cmd, struct shmid_ds* buf) { int n; void* shmaddr; n = __infer_nondet_int(); shmaddr = (void*)(long)shmid; if (cmd == IPC_RMID) free(shmaddr); return n; } void* realloc(void* ptr, size_t size) { if (ptr == 0) { // if ptr in NULL, behave as malloc return malloc(size); } int can_enlarge; __require_allocated_array(ptr); can_enlarge = __infer_nondet_int(); // nondeterministically choose whether the // current block can be enlarged if (can_enlarge) { __set_array_length(ptr, size); // enlarge the block return ptr; } int* newblock = (int*)malloc(size); if (newblock) { free(ptr); return newblock; } else { // if new allocation fails, do not free the old block return newblock; } } // modelled as a call to malloc void* calloc(size_t nmemb, size_t size) { return malloc(nmemb * size); } // character functions from ctype.h // all modelled as returning a nondeterministic value int isalnum(int x) { return __infer_nondet_int(); } int isalpha(int x) { return __infer_nondet_int(); } int isblank(int x) { return __infer_nondet_int(); } int iscntrl(int x) { return __infer_nondet_int(); } int isdigit(int x) { return __infer_nondet_int(); } int isgraph(int x) { return __infer_nondet_int(); } int islower(int x) { return __infer_nondet_int(); } int isprint(int x) { return __infer_nondet_int(); } int ispunct(int x) { return __infer_nondet_int(); } int isspace(int x) { return __infer_nondet_int(); } int isupper(int x) { return __infer_nondet_int(); } int isxdigit(int x) { return __infer_nondet_int(); } int tolower(int x) { return __infer_nondet_int(); } int toupper(int x) { return __infer_nondet_int(); } int isascii(int x) { return __infer_nondet_int(); } int toascii(int x) { return __infer_nondet_int(); } // modeled as skip. n>0 models success. // Upon successful completion a non-negative integer, namely the file // descriptor, shall be returned; // otherwise, -1 shall be returned. int dup(int fildes) { int n; n = __infer_nondet_int(); if (n > 0) return fildes; else return -1; }; // modeled as skip. // The getuid() function shall always be successful and no return value is // reserved to indicate the error. uid_t getuid(void) { return __infer_nondet_int(); }; // modeled as skip // The getpid() function shall always be successful and no return value is // reserved to indicate an error. pid_t getpid(void) { return __infer_nondet_int(); }; // modeled as skip. // success is modeled by n>0, if lseek fails (off_t)-1 should be returned. off_t lseek(int fildes, off_t offset, int whence) { int n; off_t tmp; n = __infer_nondet_int(); tmp = __infer_nondet_int(); if (n > 0) return tmp; else return (off_t)-1; }; // modeled using malloc and set file attribute DIR* opendir(const char* dirname) { DIR* ret; ret = (DIR*)malloc(sizeof(void*)); if (ret) __set_file_attribute(ret); return ret; } // modeled using free, can return EOF int closedir(DIR* dirp) { DIR tmp = *dirp; int n; n = __infer_nondet_int(); free(dirp); if (n > 0) return 0; else return EOF; } // use a global variable to model the return value of readdir extern struct dirent* _dirent_global; // dirp must be allocated // return 0 or the allocated pointerq _dirent_global, nondeterministically struct dirent* readdir(DIR* dirp) { int nondet; struct dirent* ret = _dirent_global; __require_allocated_array(dirp); nondet = __infer_nondet_int(); if (nondet) return 0; return ret; } // use a global variable to model the return value of getenv extern char* _getenv_global; // string name must be allocated // return 0 or the allocated string _getenv_global, nondeterministically char* getenv(const char* name) { int nondet; __require_allocated_array(name); __require_allocated_array(_getenv_global); nondet = __infer_nondet_int(); if (nondet) return 0; return _getenv_global; } // use a global variable to model the return value of setlocale extern char* _locale_global; // string locale must be allocated // return 0 or the allocated string _locale_global, nondeterministically char* setlocale(int category, const char* locale) { int nondet; __require_allocated_array(_locale_global); if (locale == NULL) { return _locale_global; } __require_allocated_array(locale); nondet = __infer_nondet_int(); if (nondet) return 0; return _locale_global; } // use a global variable to model the return value of localeconv extern struct lconv* _lconv_global; // return the allocated pointer _lconv_global struct lconv* localeconv() { int nondet; struct lconv tmp; tmp = *_lconv_global; return _lconv_global; } // use a global variable to model the return value of localtime extern struct tm* _tm_global; // return nondeterministically NULL or the global variable _tm_global struct tm* localtime(const time_t* clock) { int fail; fail = __infer_nondet_int(); if (fail) return NULL; else return _tm_global; } // return nondeterministically NULL or the global variable _tm_global struct tm* gmtime(const time_t* timer) { int fail; fail = __infer_nondet_int(); if (fail) return NULL; else return _tm_global; } // use a global variable to model the return value of asctime extern char* _asctime_global; // return the global variable _asctime_global char* asctime(const struct tm* timeptr) { return _asctime_global; } // modelled using asctime and localtime char* ctime(const time_t* clock) { return asctime(localtime(clock)); } // return a nondeterministic double double difftime(time_t time1, time_t time0) { return __infer_nondet_double(); } // return a nondeterministic nonnegative value or -1 time_t mktime(struct tm* timeptr) { time_t res; res = __infer_nondet_time_t(); INFER_EXCLUDE_CONDITION(res < -1); return res; } // return a nondeterministic nonnegative value or -1 clock_t clock() { clock_t res; res = __infer_nondet_clock_t(); INFER_EXCLUDE_CONDITION(res < -1); return res; } // return a nondeterministic nonnegative value size_t strftime(char* __restrict s, size_t maxsize, const char* __restrict format, const struct tm* __restrict timeptr) { size_t res; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic value of type time_t time_t time(time_t* tloc) { time_t t; t = __infer_nondet_time_t(); if (tloc) *tloc = t; return t; } // use a global variable to model the return value of getpwuid extern struct passwd* _getpwuid_global; // return either NULL or the global variable _getpwuid_global struct passwd* getpwuid(uid_t uid) { int found; found = __infer_nondet_int(); if (found) return _getpwuid_global; else return NULL; } // use a global variable to model the return value of getpwent extern struct passwd* _getpwent_global; // return either NULL or the global variable _getpwent_global struct passwd* getpwent(void) { int found; found = __infer_nondet_int(); if (found) return _getpwent_global; else return NULL; } // use a global variable to model the return value of getpwnam extern struct passwd* _getpwnam_global; // login must be allocated // return either NULL or the global variable _getpnam_global struct passwd* getpwnam(const char* login) { int found; __require_allocated_array(login); found = __infer_nondet_int(); if (found) return _getpwnam_global; else return NULL; } // nondeterministically return 0 (failure) or 1 (success) int setpassent(int stayopen) { int success; success = __infer_nondet_int(); if (success) return 1; else return 0; } // modled as skip void setpwent(void) {} // modled as skip void endpwent(void) {} // use a global variable to model the return value of getlogin extern char* _getlogin_global; // string name must be allocated // return 0 or the allocated string _getlogin_global, nondeterministically char* getlogin() { int size; int nondet; __require_allocated_array(_getlogin_global); nondet = __infer_nondet_int(); if (nondet) return 0; return _getlogin_global; } int setlogin(const char* name) { int success; __require_allocated_array(name); success = __infer_nondet_int(); if (success) { strcpy(_getlogin_global, name); return 0; } else return -1; } // use a global variable to model the return value of getpass extern char* _getpass_global; // prompt must be allocated // return the global variable _getpass_global, which must be allocated char* getpass(const char* prompt) { __require_allocated_array(prompt); __require_allocated_array(_getpass_global); return _getpass_global; } // return a nondeterministic nonnegative integer int printf(const char* format, ...) { int res; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic nonnegative integer // requires stream to be allocated int fprintf(FILE* stream, const char* format, ...) { int res; FILE tmp; tmp = *stream; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic nonnegative integer int snprintf(char* __restrict s, size_t n, const char* __restrict format, ...) { int res; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // s must be allocated // return a nondeterministic nonnegative integer int sprintf(char* s, const char* format, ...) { int res; __require_allocated_array(s); res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic nonnegative integer // requires stream to be allocated int vfprintf(FILE* stream, const char* format, va_list arg) { int res; FILE tmp; tmp = *stream; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic nonnegative integer int vsprintf(char* s, const char* format, va_list arg) { int res; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic nonnegative integer int vsnprintf(char* s, size_t n, const char* format, va_list arg) { int res; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // return a nondeterministic nonnegative integer int vprintf(const char* format, va_list arg) { int res; res = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(res < 0); return res; } // forces path to be allocated // return nondeterministically 0 or -1 int utimes(const char* path, const struct timeval times[2]) { int success = __infer_nondet_int(); __require_allocated_array(path); // return random result return (success > 0) ? 0 : -1; } // forces filename to be allocated // return nondeterministically 0 or -1 int unlink(const char* filename) { int success = __infer_nondet_int(); __require_allocated_array(filename); return (success > 0) ? 0 : -1; } // return nondeterministically 0 or -1 int usleep(useconds_t useconds) { int success = __infer_nondet_int(); return (success > 0) ? 0 : -1; } // dst and src must be allocated // return an integer between 0 and size size_t strlcpy(char* dst, const char* src, size_t size) { int size_dst; int res; res = __infer_nondet_int(); // force src to be allocated __require_allocated_array(src); // force dst to be allocated for at least size __require_allocated_array(dst); size_dst = __get_array_length(dst); INFER_EXCLUDE_CONDITION(size > size_dst); INFER_EXCLUDE_CONDITION(res > size || res < 0); return res; } // dst and src must be allocated // return an integer between 0 and size size_t strlcat(char* dst, const char* src, size_t size) { int size_dst; int res; res = __infer_nondet_int(); // force src to be allocated __require_allocated_array(src); // force dst to be allocated for at least size __require_allocated_array(dst); size_dst = __get_array_length(dst); INFER_EXCLUDE_CONDITION(size > size_dst); INFER_EXCLUDE_CONDITION(res > size || res < 0); return res; } // path must be allocated // assign nonteterministically to the contents of buf // return 0 or -1 int statfs(const char* path, struct statfs* buf) { int success; success = __infer_nondet_int(); // force path to be allocated __require_allocated_array(path); struct statfs s; // uninitialized struct statfs *buf = s; return (success > 0) ? 0 : -1; } // path must be allocated // assign nonteterministically to the contents of buf // return 0 or -1 int stat(const char* path, struct stat* buf) { int success; success = __infer_nondet_int(); // force path to be allocated __require_allocated_array(path); struct stat s; // uninitialized struct stat *buf = s; return (success > 0) ? 0 : -1; } int remove(const char* path) { int success; // force path to be allocated __require_allocated_array(path); success = __infer_nondet_int(); return (success > 0) ? 0 : -1; } char* readline(const char* prompt) { char* ret; int size; // force prompt to be allocated when not null if (prompt != NULL) { __require_allocated_array(prompt); } // return random string of positive size size = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(size < 0); ret = (char*)malloc(sizeof(size)); return ret; } long random(void) { long ret; ret = __infer_nondet_long_int(); INFER_EXCLUDE_CONDITION(ret < 0); return ret; } // requires stream to be allocated int putc(int c, FILE* stream) { int rand; FILE tmp; tmp = *stream; rand = __infer_nondet_int(); if (rand > 0) return c; // success else return EOF; // failure } int access(const char* path, int mode) { int success; // force path to be allocated __require_allocated_array(path); // determine return value success = __infer_nondet_int(); return (success > 0) ? 0 : -1; } size_t confstr(int name, char* buf, size_t len) { int ret; // determine return value ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < 0); // buf should be allocated if len is not zero. Otherwise, we want buf=0. if (len) __require_allocated_array(buf); else INFER_EXCLUDE_CONDITION(buf != 0); return ret; } // return a non-deterministic value // stream is not required to be allocated int fflush(FILE* stream) { return __infer_nondet_int(); } int flock(int fd, int operation) { int ret; ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } int fsync(int fildes) { int ret; ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } int fsctl(const char* path, unsigned long request, void* data, unsigned int options) { int ret; // forces path and data to be allocated __require_allocated_array(path); __require_allocated_array(data); ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } int getrusage(int who, struct rusage* r_usage) { int ret; INFER_EXCLUDE_CONDITION(r_usage == 0); ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } #ifdef __APPLE__ #define gettimeofday_tzp_decl void* __restrict tzp #else #ifdef __CYGWIN__ #define gettimeofday_tzp_decl void* __restrict tzp #else #define gettimeofday_tzp_decl struct timezone* __restrict tzp #endif #endif int gettimeofday(struct timeval* __restrict tp, gettimeofday_tzp_decl) { struct timeval tmp_tp; struct timezone tmp_tzp; int success; if (tp != 0) *tp = tmp_tp; if (tzp != 0) *(struct timezone*)tzp = tmp_tzp; success = __infer_nondet_int(); return success ? 0 : -1; } struct tm* localtime_r(const time_t* __restrict timer, struct tm* __restrict result) { int success; struct tm tmp; INFER_EXCLUDE_CONDITION(timer == 0); INFER_EXCLUDE_CONDITION(result == 0); success = __infer_nondet_int(); *result = tmp; return (success > 0) ? result : 0; } int mkdir(const char* filename, mode_t mode) { int ret; __require_allocated_array(filename); ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } int munmap(void* addr, size_t len) { int ret; INFER_EXCLUDE_CONDITION(addr == 0); ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } // returns a nondeterministc value int pthread_mutex_destroy(pthread_mutex_t* mutex) { INFER_EXCLUDE_CONDITION(mutex == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutex_init(pthread_mutex_t* __restrict mutex, const pthread_mutexattr_t* __restrict attr) { INFER_EXCLUDE_CONDITION(mutex == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutex_lock(pthread_mutex_t* mutex) { INFER_EXCLUDE_CONDITION(mutex == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutex_trylock(pthread_mutex_t* mutex) { INFER_EXCLUDE_CONDITION(mutex == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutex_unlock(pthread_mutex_t* mutex) { INFER_EXCLUDE_CONDITION(mutex == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutexattr_destroy(pthread_mutexattr_t* attr) { INFER_EXCLUDE_CONDITION(attr == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutexattr_init(pthread_mutexattr_t* attr) { INFER_EXCLUDE_CONDITION(attr == 0); return __infer_nondet_int(); } // returns a nondeterministc value int pthread_mutexattr_settype(pthread_mutexattr_t* attr, int type) { INFER_EXCLUDE_CONDITION(attr == 0); return __infer_nondet_int(); } // returns a nondeterministc value and forces type to be allocated and set its // content int pthread_mutexattr_gettype(const pthread_mutexattr_t* attr, int* type) { INFER_EXCLUDE_CONDITION(attr == 0); *type = __infer_nondet_int(); return __infer_nondet_int(); } // return a positive non-deterministic number or -1. // requires stream to be allocated int fileno(FILE* stream) { int ret = __infer_nondet_int(); FILE tmp; tmp = *stream; INFER_EXCLUDE_CONDITION(ret < -1 || ret == 0); return ret; } int fstat(int fildes, struct stat* buf) { int ret; struct stat s; // uninitialized struct stat *buf = s; ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } // treates as skyp. Return nondeterministically 0 or -1 int futimes(int fildes, const struct timeval times[2]) { int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } #ifdef getchar // cygwin defines getchar as a macro #undef getchar #endif int getchar(void) { // randomly produce an error int ret = __infer_nondet_int(); if (ret < 0) return EOF; else return ret; } int isatty(int fildes) { int ret; ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < 0 || ret > 1); return ret; } void perror(const char* s) { __require_allocated_array(s); } int pipe(int fildes[2]) { int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } int raise(int sig) { return __infer_nondet_int(); } ssize_t read(int fildes, void* buf, size_t nbyte) { if (nbyte == 0) return 0; __require_allocated_array(buf); INFER_EXCLUDE_CONDITION(__get_array_length(buf) < nbyte); int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > nbyte); return ret; } int sigaction(int sig, const struct sigaction* act, struct sigaction* oact) { int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || ret > 0); return ret; } // return the first argument // long __builtin_expect(long x, long y) { // return x; //} // TODO: this function has been disabled because it cannot be compiled with // LLVM. // It is normally a builtin that should not be implemented and LLVM complains // about this #ifdef clearerr // cygwin defines clearerr as a macro #undef clearerr #endif // modelled as skip // stream is required to be allocated void clearerr(FILE* stream) { FILE tmp; tmp = *stream; } #ifdef ferror // cygwin defines ferror as a macro #undef ferror #endif // return a nondeterministic value // stream required to be allocated int ferror(FILE* stream) { FILE tmp; tmp = *stream; return __infer_nondet_int(); } #ifdef feof // cygwin defines feof as a macro #undef feof #endif // return a nondeterministic value // stream required to be allocated int feof(FILE* stream) { FILE tmp; tmp = *stream; return __infer_nondet_int(); } // write to *pos and return either 0 or -1 // stream is required to be allocated int fgetpos(FILE* __restrict stream, fpos_t* __restrict pos) { int success; FILE tmp; tmp = *stream; #ifdef __APPLE__ // fpos_t is a long in MacOS, but a struct in Linux. *pos = __infer_nondet_long_int(); #else pos->__pos = __infer_nondet_long_int(); #endif success = __infer_nondet_int(); if (success) return 0; else return -1; } // read from *pos and return either 0 or -1 // stream is required to be allocated int fsetpos(FILE* stream, const fpos_t* pos) { int success; FILE tmp; tmp = *stream; fpos_t t; t = *pos; success = __infer_nondet_int(); if (success) return 0; else return -1; } // return a value between 0 and nmemb size_t fread(void* __restrict ptr, size_t size, size_t nmemb, FILE* __restrict stream) { size_t res; res = __infer_nondet_size_t(); if (size == 0 || nmemb == 0) return 0; INFER_EXCLUDE_CONDITION(res < 0 || res > nmemb); return res; } // return a value between 0 and nmemb size_t fwrite(const void* __restrict ptr, size_t size, size_t nmemb, FILE* __restrict stream) { size_t res; res = __infer_nondet_size_t(); if (size == 0 || nmemb == 0) return 0; INFER_EXCLUDE_CONDITION(res < 0 || res > nmemb); return res; } size_t strcspn(const char* s1, const char* s2) { __require_allocated_array(s1); __require_allocated_array(s2); int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < 0); return ret; } // There is non-standard version of strerr_r: // http://linux.die.net/man/3/strerror_r // It's not modelled right now #if defined __APPLE__ || (defined __USE_XOPEN2K && !defined __USE_GNU) int strerror_r(int errnum, char* strerrbuf, size_t buflen) { __require_allocated_array(strerrbuf); INFER_EXCLUDE_CONDITION(__get_array_length(strerrbuf) < buflen); return __infer_nondet_int(); } #endif ssize_t write(int fildes, const void* buf, size_t nbyte) { __require_allocated_array(buf); INFER_EXCLUDE_CONDITION(__get_array_length(buf) < nbyte); int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || nbyte < ret); return ret; } int creat(const char* path, mode_t mode) { __require_allocated_array(path); int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1); return ret; } // modeled as skip int fcntl(int fildes, int cmd, ...) { int ret = __infer_nondet_int(); return ret; } // modelled as skip int sigprocmask(int how, const sigset_t* set, sigset_t* oset) { int ret = __infer_nondet_int(); INFER_EXCLUDE_CONDITION(ret < -1 || 0 < ret); return ret; } // modelled as skip void setbuf(FILE* __restrict stream, char* __restrict buf) {} // return nondeterministically 0 or EOF int setvbuf(FILE* __restrict stream, char* __restrict buf, int mode, size_t size) { int n; n = __infer_nondet_int(); if (n) return 0; else return EOF; } // the array base must be allocated with at least nmemb elements // nondeterministically return 0 or a pointer inside the array void* bsearch(const void* key, const void* base, size_t nmemb, size_t size, int (*compar)(const void*, const void*)) { int base_size; int nondet; int offset; nondet = __infer_nondet_int(); offset = __infer_nondet_int(); __require_allocated_array(base); base_size = __get_array_length(base); INFER_EXCLUDE_CONDITION(nmemb > base_size); if (nondet) return 0; INFER_EXCLUDE_CONDITION(offset < 0 || offset >= nmemb); return (char*)base + offset; } // return a nondeterministic value int mblen(const char* s, size_t n) { return __infer_nondet_int(); } // return a nondeterministic value size_t mbstowcs(wchar_t* __restrict pwcs, const char* __restrict s, size_t n) { return (size_t)__infer_nondet_int(); } // return a nondeterministic value int mbtowc(wchar_t* __restrict pwc, const char* __restrict s, size_t n) { return __infer_nondet_int(); } // modeled as skip void qsort(void* base, size_t nmemb, size_t size, int (*compar)(const void*, const void*)) {} // return a nondeterministic value int strcoll(const char* s1, const char* s2) { return __infer_nondet_int(); } // return a nondeterministic value size_t wcstombs(char* __restrict s, const wchar_t* __restrict pwcs, size_t n) { return (size_t)__infer_nondet_int(); } // return a nondeterministic value int wctomb(char* s, wchar_t wc) { return __infer_nondet_int(); } // modeled like open int socket(int namespace_, int style, int protocol) { int* ret = (int*)malloc(sizeof(int)); if (ret) { __set_file_attribute(ret); INFER_EXCLUDE_CONDITION(ret < (int*)1); // force result to be > 0 return (size_t)ret; } return -1; } void* xcalloc(size_t nmemb, size_t size) { void* ret = calloc(nmemb, size); INFER_EXCLUDE_CONDITION(ret == NULL); return ret; } void* xmalloc(size_t size) { void* ret = malloc(size); INFER_EXCLUDE_CONDITION(ret == NULL); return ret; }