/* * Copyright (C) 2008-2012 Tobias Brunner * Copyright (C) 2005-2008 Martin Willi * Hochschule fuer Technik Rapperswil * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. See . * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. */ #include "utils.h" #include #include #include #include #include #include #include #include #include #include #include "collections/enumerator.h" #include "utils/debug.h" ENUM(status_names, SUCCESS, NEED_MORE, "SUCCESS", "FAILED", "OUT_OF_RES", "ALREADY_DONE", "NOT_SUPPORTED", "INVALID_ARG", "NOT_FOUND", "PARSE_ERROR", "VERIFY_ERROR", "INVALID_STATE", "DESTROY_ME", "NEED_MORE", ); /** * Described in header. */ void *clalloc(void * pointer, size_t size) { void *data; data = malloc(size); memcpy(data, pointer, size); return (data); } /** * Described in header. */ void memxor(u_int8_t dst[], u_int8_t src[], size_t n) { int m, i; /* byte wise XOR until dst aligned */ for (i = 0; (uintptr_t)&dst[i] % sizeof(long) && i < n; i++) { dst[i] ^= src[i]; } /* try to use words if src shares an aligment with dst */ switch (((uintptr_t)&src[i] % sizeof(long))) { case 0: for (m = n - sizeof(long); i <= m; i += sizeof(long)) { *(long*)&dst[i] ^= *(long*)&src[i]; } break; case sizeof(int): for (m = n - sizeof(int); i <= m; i += sizeof(int)) { *(int*)&dst[i] ^= *(int*)&src[i]; } break; case sizeof(short): for (m = n - sizeof(short); i <= m; i += sizeof(short)) { *(short*)&dst[i] ^= *(short*)&src[i]; } break; default: break; } /* byte wise XOR of the rest */ for (; i < n; i++) { dst[i] ^= src[i]; } } /** * Described in header. */ void memwipe_noinline(void *ptr, size_t n) { memwipe_inline(ptr, n); } /** * Described in header. */ void *memstr(const void *haystack, const char *needle, size_t n) { unsigned const char *pos = haystack; size_t l = strlen(needle); for (; n >= l; ++pos, --n) { if (memeq(pos, needle, l)) { return (void*)pos; } } return NULL; } /** * Described in header. */ char* translate(char *str, const char *from, const char *to) { char *pos = str; if (strlen(from) != strlen(to)) { return str; } while (pos && *pos) { char *match; if ((match = strchr(from, *pos)) != NULL) { *pos = to[match - from]; } pos++; } return str; } /** * Described in header. */ bool mkdir_p(const char *path, mode_t mode) { int len; char *pos, full[PATH_MAX]; pos = full; if (!path || *path == '\0') { return TRUE; } len = snprintf(full, sizeof(full)-1, "%s", path); if (len < 0 || len >= sizeof(full)-1) { DBG1(DBG_LIB, "path string %s too long", path); return FALSE; } /* ensure that the path ends with a '/' */ if (full[len-1] != '/') { full[len++] = '/'; full[len] = '\0'; } /* skip '/' at the beginning */ while (*pos == '/') { pos++; } while ((pos = strchr(pos, '/'))) { *pos = '\0'; if (access(full, F_OK) < 0) { if (mkdir(full, mode) < 0) { DBG1(DBG_LIB, "failed to create directory %s", full); return FALSE; } } *pos = '/'; pos++; } return TRUE; } ENUM(tty_color_names, TTY_RESET, TTY_BG_DEF, "\e[0m", "\e[1m", "\e[4m", "\e[5m", "\e[30m", "\e[31m", "\e[32m", "\e[33m", "\e[34m", "\e[35m", "\e[36m", "\e[37m", "\e[39m", "\e[40m", "\e[41m", "\e[42m", "\e[43m", "\e[44m", "\e[45m", "\e[46m", "\e[47m", "\e[49m", ); /** * Get the escape string for a given TTY color, empty string on non-tty FILE */ char* tty_escape_get(int fd, tty_escape_t escape) { if (!isatty(fd)) { return ""; } switch (escape) { case TTY_RESET: case TTY_BOLD: case TTY_UNDERLINE: case TTY_BLINKING: case TTY_FG_BLACK: case TTY_FG_RED: case TTY_FG_GREEN: case TTY_FG_YELLOW: case TTY_FG_BLUE: case TTY_FG_MAGENTA: case TTY_FG_CYAN: case TTY_FG_WHITE: case TTY_FG_DEF: case TTY_BG_BLACK: case TTY_BG_RED: case TTY_BG_GREEN: case TTY_BG_YELLOW: case TTY_BG_BLUE: case TTY_BG_MAGENTA: case TTY_BG_CYAN: case TTY_BG_WHITE: case TTY_BG_DEF: return enum_to_name(tty_color_names, escape); /* warn if a excape code is missing */ } return ""; } /** * The size of the thread-specific error buffer */ #define STRERROR_BUF_LEN 256 /** * Key to store thread-specific error buffer */ static pthread_key_t strerror_buf_key; /** * Only initialize the key above once */ static pthread_once_t strerror_buf_key_once = PTHREAD_ONCE_INIT; /** * Create the key used for the thread-specific error buffer */ static void create_strerror_buf_key() { pthread_key_create(&strerror_buf_key, free); } /** * Retrieve the error buffer assigned to the current thread (or create it) */ static inline char *get_strerror_buf() { char *buf; pthread_once(&strerror_buf_key_once, create_strerror_buf_key); buf = pthread_getspecific(strerror_buf_key); if (!buf) { buf = malloc(STRERROR_BUF_LEN); pthread_setspecific(strerror_buf_key, buf); } return buf; } #ifdef HAVE_STRERROR_R /* * Described in header. */ const char *safe_strerror(int errnum) { char *buf = get_strerror_buf(), *msg; #ifdef STRERROR_R_CHAR_P /* char* version which may or may not return the original buffer */ msg = strerror_r(errnum, buf, STRERROR_BUF_LEN); #else /* int version returns 0 on success */ msg = strerror_r(errnum, buf, STRERROR_BUF_LEN) ? "Unknown error" : buf; #endif return msg; } #else /* HAVE_STRERROR_R */ /* we actually wan't to call strerror(3) below */ #undef strerror /* * Described in header. */ const char *safe_strerror(int errnum) { static pthread_mutex_t mutex = PTHREAD_MUTEX_INITIALIZER; char *buf = get_strerror_buf(); /* use a mutex to ensure calling strerror(3) is thread-safe */ pthread_mutex_lock(&mutex); strncpy(buf, strerror(errnum), STRERROR_BUF_LEN); pthread_mutex_unlock(&mutex); buf[STRERROR_BUF_LEN - 1] = '\0'; return buf; } #endif /* HAVE_STRERROR_R */ #ifndef HAVE_CLOSEFROM /** * Described in header. */ void closefrom(int lowfd) { char fd_dir[PATH_MAX]; int maxfd, fd, len; /* try to close only open file descriptors on Linux... */ len = snprintf(fd_dir, sizeof(fd_dir), "/proc/%u/fd", getpid()); if (len > 0 && len < sizeof(fd_dir) && access(fd_dir, F_OK) == 0) { enumerator_t *enumerator = enumerator_create_directory(fd_dir); if (enumerator) { char *rel; while (enumerator->enumerate(enumerator, &rel, NULL, NULL)) { fd = atoi(rel); if (fd >= lowfd) { close(fd); } } enumerator->destroy(enumerator); return; } } /* ...fall back to closing all fds otherwise */ maxfd = (int)sysconf(_SC_OPEN_MAX); if (maxfd < 0) { maxfd = 256; } for (fd = lowfd; fd < maxfd; fd++) { close(fd); } } #endif /* HAVE_CLOSEFROM */ /** * Return monotonic time */ time_t time_monotonic(timeval_t *tv) { #if defined(HAVE_CLOCK_GETTIME) && \ (defined(HAVE_CONDATTR_CLOCK_MONOTONIC) || \ defined(HAVE_PTHREAD_COND_TIMEDWAIT_MONOTONIC)) /* as we use time_monotonic() for condvar operations, we use the * monotonic time source only if it is also supported by pthread. */ timespec_t ts; if (clock_gettime(CLOCK_MONOTONIC, &ts) == 0) { if (tv) { tv->tv_sec = ts.tv_sec; tv->tv_usec = ts.tv_nsec / 1000; } return ts.tv_sec; } #endif /* HAVE_CLOCK_GETTIME && (...) */ /* Fallback to non-monotonic timestamps: * On MAC OS X, creating monotonic timestamps is rather difficult. We * could use mach_absolute_time() and catch sleep/wakeup notifications. * We stick to the simpler (non-monotonic) gettimeofday() for now. * But keep in mind: we need the same time source here as in condvar! */ if (!tv) { return time(NULL); } if (gettimeofday(tv, NULL) != 0) { /* should actually never fail if passed pointers are valid */ return -1; } return tv->tv_sec; } /** * return null */ void *return_null() { return NULL; } /** * returns TRUE */ bool return_true() { return TRUE; } /** * returns FALSE */ bool return_false() { return FALSE; } /** * returns FAILED */ status_t return_failed() { return FAILED; } /** * returns SUCCESS */ status_t return_success() { return SUCCESS; } /** * nop operation */ void nop() { } #ifndef HAVE_GCC_ATOMIC_OPERATIONS /** * We use a single mutex for all refcount variables. */ static pthread_mutex_t ref_mutex = PTHREAD_MUTEX_INITIALIZER; /** * Increase refcount */ void ref_get(refcount_t *ref) { pthread_mutex_lock(&ref_mutex); (*ref)++; pthread_mutex_unlock(&ref_mutex); } /** * Decrease refcount */ bool ref_put(refcount_t *ref) { bool more_refs; pthread_mutex_lock(&ref_mutex); more_refs = --(*ref) > 0; pthread_mutex_unlock(&ref_mutex); return !more_refs; } /** * Single mutex for all compare and swap operations. */ static pthread_mutex_t cas_mutex = PTHREAD_MUTEX_INITIALIZER; /** * Compare and swap if equal to old value */ #define _cas_impl(name, type) \ bool cas_##name(type *ptr, type oldval, type newval) \ { \ bool swapped; \ pthread_mutex_lock(&cas_mutex); \ if ((swapped = (*ptr == oldval))) { *ptr = newval; } \ pthread_mutex_unlock(&cas_mutex); \ return swapped; \ } _cas_impl(bool, bool) _cas_impl(ptr, void*) #endif /* HAVE_GCC_ATOMIC_OPERATIONS */ /** * Described in header. */ int time_printf_hook(printf_hook_data_t *data, printf_hook_spec_t *spec, const void *const *args) { static const char* months[] = { "Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec" }; time_t *time = *((time_t**)(args[0])); bool utc = *((bool*)(args[1]));; struct tm t; if (*time == UNDEFINED_TIME) { return print_in_hook(data, "--- -- --:--:--%s----", utc ? " UTC " : " "); } if (utc) { gmtime_r(time, &t); } else { localtime_r(time, &t); } return print_in_hook(data, "%s %02d %02d:%02d:%02d%s%04d", months[t.tm_mon], t.tm_mday, t.tm_hour, t.tm_min, t.tm_sec, utc ? " UTC " : " ", t.tm_year + 1900); } /** * Described in header. */ int time_delta_printf_hook(printf_hook_data_t *data, printf_hook_spec_t *spec, const void *const *args) { char* unit = "second"; time_t *arg1 = *((time_t**)(args[0])); time_t *arg2 = *((time_t**)(args[1])); u_int64_t delta = llabs(*arg1 - *arg2); if (delta > 2 * 60 * 60 * 24) { delta /= 60 * 60 * 24; unit = "day"; } else if (delta > 2 * 60 * 60) { delta /= 60 * 60; unit = "hour"; } else if (delta > 2 * 60) { delta /= 60; unit = "minute"; } return print_in_hook(data, "%" PRIu64 " %s%s", delta, unit, (delta == 1) ? "" : "s"); } /** * Number of bytes per line to dump raw data */ #define BYTES_PER_LINE 16 static char hexdig_upper[] = "0123456789ABCDEF"; /** * Described in header. */ int mem_printf_hook(printf_hook_data_t *data, printf_hook_spec_t *spec, const void *const *args) { char *bytes = *((void**)(args[0])); u_int len = *((int*)(args[1])); char buffer[BYTES_PER_LINE * 3]; char ascii_buffer[BYTES_PER_LINE + 1]; char *buffer_pos = buffer; char *bytes_pos = bytes; char *bytes_roof = bytes + len; int line_start = 0; int i = 0; int written = 0; written += print_in_hook(data, "=> %u bytes @ %p", len, bytes); while (bytes_pos < bytes_roof) { *buffer_pos++ = hexdig_upper[(*bytes_pos >> 4) & 0xF]; *buffer_pos++ = hexdig_upper[ *bytes_pos & 0xF]; ascii_buffer[i++] = (*bytes_pos > 31 && *bytes_pos < 127) ? *bytes_pos : '.'; if (++bytes_pos == bytes_roof || i == BYTES_PER_LINE) { int padding = 3 * (BYTES_PER_LINE - i); while (padding--) { *buffer_pos++ = ' '; } *buffer_pos++ = '\0'; ascii_buffer[i] = '\0'; written += print_in_hook(data, "\n%4d: %s %s", line_start, buffer, ascii_buffer); buffer_pos = buffer; line_start += BYTES_PER_LINE; i = 0; } else { *buffer_pos++ = ' '; } } return written; }