static void print_context_label (char const *mark, struct file_data *inf, char const *name, char const *label) { if (label) fprintf (outfile, "%s %s\n", mark, label); else { char buf[MAX (INT_STRLEN_BOUND (int) + 32, INT_STRLEN_BOUND (time_t) + 11)]; struct tm const *tm = localtime (&inf->stat.st_mtime); int nsec = get_stat_mtime_ns (&inf->stat); if (! (tm && nstrftime (buf, sizeof buf, time_format, tm, 0, nsec))) { verify (TYPE_IS_INTEGER (time_t)); if (LONG_MIN <= TYPE_MINIMUM (time_t) && TYPE_MAXIMUM (time_t) <= LONG_MAX) { long int sec = inf->stat.st_mtime; sprintf (buf, "%ld.%.9d", sec, nsec); } else if (TYPE_MAXIMUM (time_t) <= INTMAX_MAX) { intmax_t sec = inf->stat.st_mtime; sprintf (buf, "%"PRIdMAX".%.9d", sec, nsec); } else { uintmax_t sec = inf->stat.st_mtime; sprintf (buf, "%"PRIuMAX".%.9d", sec, nsec); } } fprintf (outfile, "%s %s\t%s\n", mark, name, buf); } }
int utimecmp (char const *dst_name, struct stat const *dst_stat, struct stat const *src_stat, int options) { /* Things to watch out for: The code uses a static hash table internally and is not safe in the presence of signals, multiple threads, etc. int and long int might be 32 bits. Many of the calculations store numbers up to 2 billion, and multiply by 10; they have to avoid multiplying 2 billion by 10, as this exceeds 32-bit capabilities. time_t might be unsigned. */ verify (TYPE_IS_INTEGER (time_t)); verify (TYPE_TWOS_COMPLEMENT (int)); /* Destination and source time stamps. */ time_t dst_s = dst_stat->st_mtime; time_t src_s = src_stat->st_mtime; int dst_ns = get_stat_mtime_ns (dst_stat); int src_ns = get_stat_mtime_ns (src_stat); if (options & UTIMECMP_TRUNCATE_SOURCE) { /* Look up the time stamp resolution for the destination device. */ /* Hash table for devices. */ static Hash_table *ht; /* Information about the destination file system. */ static struct fs_res *new_dst_res; struct fs_res *dst_res; /* Time stamp resolution in nanoseconds. */ int res; if (! ht) ht = hash_initialize (16, NULL, dev_info_hash, dev_info_compare, free); if (! new_dst_res) { new_dst_res = xmalloc (sizeof *new_dst_res); new_dst_res->resolution = 2 * BILLION; new_dst_res->exact = false; } new_dst_res->dev = dst_stat->st_dev; dst_res = hash_insert (ht, new_dst_res); if (! dst_res) xalloc_die (); if (dst_res == new_dst_res) { /* NEW_DST_RES is now in use in the hash table, so allocate a new entry next time. */ new_dst_res = NULL; } res = dst_res->resolution; if (! dst_res->exact) { /* This file system's resolution is not known exactly. Deduce it, and store the result in the hash table. */ time_t dst_a_s = dst_stat->st_atime; time_t dst_c_s = dst_stat->st_ctime; time_t dst_m_s = dst_s; int dst_a_ns = get_stat_atime_ns (dst_stat); int dst_c_ns = get_stat_ctime_ns (dst_stat); int dst_m_ns = dst_ns; /* Set RES to an upper bound on the file system resolution (after truncation due to SYSCALL_RESOLUTION) by inspecting the atime, ctime and mtime of the existing destination. We don't know of any file system that stores atime or ctime with a higher precision than mtime, so it's valid to look at them too. */ { bool odd_second = (dst_a_s | dst_c_s | dst_m_s) & 1; if (SYSCALL_RESOLUTION == BILLION) { if (odd_second | dst_a_ns | dst_c_ns | dst_m_ns) res = BILLION; } else { int a = dst_a_ns; int c = dst_c_ns; int m = dst_m_ns; /* Write it this way to avoid mistaken GCC warning about integer overflow in constant expression. */ int SR10 = SYSCALL_RESOLUTION; SR10 *= 10; if ((a % SR10 | c % SR10 | m % SR10) != 0) res = SYSCALL_RESOLUTION; else for (res = SR10, a /= SR10, c /= SR10, m /= SR10; (res < dst_res->resolution && (a % 10 | c % 10 | m % 10) == 0); res *= 10, a /= 10, c /= 10, m /= 10) if (res == BILLION) { if (! odd_second) res *= 2; break; } } dst_res->resolution = res; } if (SYSCALL_RESOLUTION < res) { struct timespec timespec[2]; struct stat dst_status; /* Ignore source time stamp information that must necessarily be lost when filtered through utimens. */ src_ns -= src_ns % SYSCALL_RESOLUTION; /* If the time stamps disagree widely enough, there's no need to interrogate the file system to deduce the exact time stamp resolution; return the answer directly. */ { time_t s = src_s & ~ (res == 2 * BILLION); if (src_s < dst_s || (src_s == dst_s && src_ns <= dst_ns)) return 1; if (dst_s < s || (dst_s == s && dst_ns < src_ns - src_ns % res)) return -1; } /* Determine the actual time stamp resolution for the destination file system (after truncation due to SYSCALL_RESOLUTION) by setting the access time stamp of the destination to the existing access time, except with trailing nonzero digits. */ timespec[0].tv_sec = dst_a_s; timespec[0].tv_nsec = dst_a_ns; timespec[1].tv_sec = dst_m_s | (res == 2 * BILLION); timespec[1].tv_nsec = dst_m_ns + res / 9; /* Set the modification time. But don't try to set the modification time of symbolic links; on many hosts this sets the time of the pointed-to file. */ if (S_ISLNK (dst_stat->st_mode) || utimens (dst_name, timespec) != 0) return -2; /* Read the modification time that was set. It's safe to call 'stat' here instead of worrying about 'lstat'; either the caller used 'stat', or the caller used 'lstat' and found something other than a symbolic link. */ { int stat_result = stat (dst_name, &dst_status); if (stat_result | (dst_status.st_mtime ^ dst_m_s) | (get_stat_mtime_ns (&dst_status) ^ dst_m_ns)) { /* The modification time changed, or we can't tell whether it changed. Change it back as best we can. */ timespec[1].tv_sec = dst_m_s; timespec[1].tv_nsec = dst_m_ns; utimens (dst_name, timespec); } if (stat_result != 0) return -2; } /* Determine the exact resolution from the modification time that was read back. */ { int old_res = res; int a = (BILLION * (dst_status.st_mtime & 1) + get_stat_mtime_ns (&dst_status)); res = SYSCALL_RESOLUTION; for (a /= res; a % 10 != 0; a /= 10) { if (res == BILLION) { res *= 2; break; } res *= 10; if (res == old_res) break; } } } dst_res->resolution = res; dst_res->exact = true; } /* Truncate the source's time stamp according to the resolution. */ src_s &= ~ (res == 2 * BILLION); src_ns -= src_ns % res; } /* Compare the time stamps and return -1, 0, 1 accordingly. */ return (dst_s < src_s ? -1 : dst_s > src_s ? 1 : dst_ns < src_ns ? -1 : dst_ns > src_ns); }