/* sort - sort lines of text (with all kinds of options). Copyright (C) 1988, 1991, 1992, 1993, 1994, 1995 Free Software Foundation 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, or (at your option) any later version. 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. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. Written December 1988 by Mike Haertel. The author may be reached (Email) at the address mike@gnu.ai.mit.edu, or (US mail) as Mike Haertel c/o Free Software Foundation. */ /* * $FreeBSD: src/gnu/usr.bin/sort/sort.c,v 1.15.2.4 2002/04/17 11:41:42 ache Exp $ * $DragonFly: src/gnu/usr.bin/sort/sort.c,v 1.3 2004/02/03 19:22:59 dillon Exp $ */ #include /* Get isblank from GNU libc. */ #define _GNU_SOURCE #include #include #include #ifdef __DragonFly__ #include #endif #include "system.h" #include "version.h" #include "long-options.h" #include "error.h" #include "xstrtod.h" #ifdef HAVE_LIMITS_H #include #else #ifndef UCHAR_MAX #define UCHAR_MAX 255 #endif #endif #ifndef STDC_HEADERS char *malloc (); char *realloc (); void free (); #endif /* Undefine, to avoid warning about redefinition on some systems. */ #undef min #define min(a, b) ((a) < (b) ? (a) : (b)) #define UCHAR_LIM (UCHAR_MAX + 1) #define UCHAR(c) ((unsigned char) (c)) #ifndef DEFAULT_TMPDIR #define DEFAULT_TMPDIR "/tmp" #endif /* The kind of blanks for '-b' to skip in various options. */ enum blanktype { bl_start, bl_end, bl_both }; /* Lines are held in core as counted strings. */ struct line { char *text; /* Text of the line. */ int length; /* Length not including final newline. */ char *keybeg; /* Start of first key. */ char *keylim; /* Limit of first key. */ }; /* Arrays of lines. */ struct lines { struct line *lines; /* Dynamically allocated array of lines. */ int used; /* Number of slots used. */ int alloc; /* Number of slots allocated. */ int limit; /* Max number of slots to allocate. */ }; /* Input buffers. */ struct buffer { char *buf; /* Dynamically allocated buffer. */ int used; /* Number of bytes used. */ int alloc; /* Number of bytes allocated. */ int left; /* Number of bytes left after line parsing. */ }; struct keyfield { int sword; /* Zero-origin 'word' to start at. */ int schar; /* Additional characters to skip. */ int skipsblanks; /* Skip leading white space at start. */ int eword; /* Zero-origin first word after field. */ int echar; /* Additional characters in field. */ int skipeblanks; /* Skip trailing white space at finish. */ int *ignore; /* Boolean array of characters to ignore. */ char *translate; /* Translation applied to characters. */ int numeric; /* Flag for numeric comparison. Handle strings of digits with optional decimal point, but no exponential notation. */ int general_numeric; /* Flag for general, numeric comparison. Handle numbers in exponential notation. */ int month; /* Flag for comparison by month name. */ int reverse; /* Reverse the sense of comparison. */ struct keyfield *next; /* Next keyfield to try. */ }; struct month { char *name; int val; }; /* The name this program was run with. */ char *program_name; /* Table of digits. */ static int digits[UCHAR_LIM]; /* Table of white space. */ static int blanks[UCHAR_LIM]; /* Table of non-printing characters. */ static int nonprinting[UCHAR_LIM]; /* Table of non-dictionary characters (not letters, digits, or blanks). */ static int nondictionary[UCHAR_LIM]; /* Translation table folding lower case to upper. */ static char fold_toupper[UCHAR_LIM]; /* Table mapping 3-letter month names to integers. Alphabetic order allows binary search. */ static struct month const monthtab[] = { {"APR", 4}, {"AUG", 8}, {"DEC", 12}, {"FEB", 2}, {"JAN", 1}, {"JUL", 7}, {"JUN", 6}, {"MAR", 3}, {"MAY", 5}, {"NOV", 11}, {"OCT", 10}, {"SEP", 9} }; /* During the merge phase, the number of files to merge at once. */ #define NMERGE 16 /* Initial buffer size for in core sorting. Will not grow unless a line longer than this is seen. */ static int sortalloc = 512 * 1024; /* Initial buffer size for in core merge buffers. Bear in mind that up to NMERGE * mergealloc bytes may be allocated for merge buffers. */ static int mergealloc = 16 * 1024; /* Guess of average line length. */ static int linelength = 30; /* Maximum number of elements for the array(s) of struct line's, in bytes. */ #define LINEALLOC (256 * 1024) /* Prefix for temporary file names. */ static char *temp_file_prefix; /* Flag to reverse the order of all comparisons. */ static int reverse; /* Flag for stable sort. This turns off the last ditch bytewise comparison of lines, and instead leaves lines in the same order they were read if all keys compare equal. */ static int stable; /* Tab character separating fields. If NUL, then fields are separated by the empty string between a non-whitespace character and a whitespace character. */ static char tab; /* Flag to remove consecutive duplicate lines from the output. Only the last of a sequence of equal lines will be output. */ static int unique; /* Nonzero if any of the input files are the standard input. */ static int have_read_stdin; /* Lists of key field comparisons to be tried. */ static struct keyfield keyhead; #ifdef __DragonFly__ static unsigned char decimal_point; static int COLLDIFF (int a, int b) { static char s[2][2]; if ((unsigned char)a == (unsigned char)b) return 0; s[0][0] = a; s[1][0] = b; return strcoll(s[0], s[1]); } static int collcmp(char *a, char *b, int mini) { char sa, sb; int r; sa = a[mini]; a[mini] = '\0'; sb = b[mini]; b[mini] = '\0'; r = strcoll(a, b); a[mini] = sa; b[mini] = sb; return r; } #endif /* __DragonFly__ */ static void usage (int status) { if (status != 0) fprintf (stderr, _("Try `%s --help' for more information.\n"), program_name); else { printf (_("\ Usage: %s [OPTION]... [FILE]...\n\ "), program_name); printf (_("\ Write sorted concatenation of all FILE(s) to standard output.\n\ \n\ +POS1 [-POS2] start a key at POS1, end it before POS2\n\ -M compare (unknown) < `JAN' < ... < `DEC', imply -b\n\ -T DIRECT use DIRECT for temporary files, not $TMPDIR or %s\n\ -b ignore leading blanks in sort fields or keys\n\ -c check if given files already sorted, do not sort\n\ -d consider only [a-zA-Z0-9 ] characters in keys\n\ -f fold lower case to upper case characters in keys\n\ -g compare according to general numerical value, imply -b\n\ -i consider only [\\040-\\0176] characters in keys\n\ -k POS1[,POS2] same as +POS1 [-POS2], but all positions counted from 1\n\ -m merge already sorted files, do not sort\n\ -n compare according to string numerical value, imply -b\n\ -o FILE write result on FILE instead of standard output\n\ -r reverse the result of comparisons\n\ -s stabilize sort by disabling last resort comparison\n\ -t SEP use SEParator instead of non- to whitespace transition\n\ -u with -c, check for strict ordering\n\ -u with -m, only output the first of an equal sequence\n\ --help display this help and exit\n\ --version output version information and exit\n\ \n\ POS is F[.C][OPTS], where F is the field number and C the character\n\ position in the field, both counted from zero. OPTS is made up of one\n\ or more of Mbdfinr, this effectively disable global -Mbdfinr settings\n\ for that key. If no key given, use the entire line as key. With no\n\ FILE, or when FILE is -, read standard input.\n\ ") , DEFAULT_TMPDIR); } exit (status); } /* The list of temporary files. */ static struct tempnode { char *name; struct tempnode *next; } temphead; /* Clean up any remaining temporary files. */ static void cleanup (void) { struct tempnode *node; for (node = temphead.next; node; node = node->next) unlink (node->name); } /* Allocate N bytes of memory dynamically, with error checking. */ static char * xmalloc (unsigned int n) { char *p; p = malloc (n); if (p == 0) { error (0, 0, _("virtual memory exhausted")); cleanup (); exit (2); } return p; } /* Change the size of an allocated block of memory P to N bytes, with error checking. If P is NULL, run xmalloc. If N is 0, run free and return NULL. */ static char * xrealloc (char *p, unsigned int n) { if (p == 0) return xmalloc (n); if (n == 0) { free (p); return 0; } p = realloc (p, n); if (p == 0) { error (0, 0, _("virtual memory exhausted")); cleanup (); exit (2); } return p; } static FILE * xtmpfopen (const char *file) { FILE *fp; int fd; fd = open (file, O_WRONLY | O_CREAT | O_TRUNC, 0600); if (fd < 0 || (fp = fdopen (fd, "w")) == NULL) { error (0, errno, "%s", file); cleanup (); exit (2); } return fp; } static FILE * xfopen (const char *file, const char *how) { FILE *fp; if (strcmp (file, "-") == 0) { fp = stdin; } else { if ((fp = fopen (file, how)) == NULL) { error (0, errno, "%s", file); cleanup (); exit (2); } } if (fp == stdin) have_read_stdin = 1; return fp; } static void xfclose (FILE *fp) { if (fp == stdin) { /* Allow reading stdin from tty more than once. */ if (feof (fp)) clearerr (fp); } else if (fp == stdout) { if (fflush (fp) != 0) { error (0, errno, _("flushing file")); cleanup (); exit (2); } } else { if (fclose (fp) != 0) { error (0, errno, _("error closing file")); cleanup (); exit (2); } } } static void xfwrite (const char *buf, int size, int nelem, FILE *fp) { if (fwrite (buf, size, nelem, fp) != nelem) { error (0, errno, _("write error")); cleanup (); exit (2); } } /* Return a name for a temporary file. */ static char * tempname (void) { int fd; int len = strlen (temp_file_prefix); char *name = xmalloc (len + 1 + sizeof ("sort") - 1 + 5 + 5 + 1); struct tempnode *node; node = (struct tempnode *) xmalloc (sizeof (struct tempnode)); sprintf (name, "%s%ssortXXXXXX", temp_file_prefix, (len && temp_file_prefix[len - 1] != '/') ? "/" : ""); if ((fd = mkstemp(name)) == -1) { error (0, errno, _("mkstemp error")); cleanup (); exit (2); } close(fd); node->name = name; node->next = temphead.next; temphead.next = node; return name; } /* Search through the list of temporary files for NAME; remove it if it is found on the list. */ static void zaptemp (char *name) { struct tempnode *node, *temp; for (node = &temphead; node->next; node = node->next) if (!strcmp (name, node->next->name)) break; if (node->next) { temp = node->next; unlink (temp->name); free (temp->name); node->next = temp->next; free ((char *) temp); } } /* Initialize the character class tables. */ static void inittables (void) { int i; for (i = 0; i < UCHAR_LIM; ++i) { if (ISBLANK (i)) blanks[i] = 1; if (ISDIGIT (i)) digits[i] = 1; if (!ISPRINT (i)) nonprinting[i] = 1; if (!ISALNUM (i) && !ISBLANK (i)) nondictionary[i] = 1; if (ISLOWER (i)) fold_toupper[i] = toupper (i); else fold_toupper[i] = i; } } /* Initialize BUF, allocating ALLOC bytes initially. */ static void initbuf (struct buffer *buf, int alloc) { buf->alloc = alloc; buf->buf = xmalloc (buf->alloc); buf->used = buf->left = 0; } /* Fill BUF reading from FP, moving buf->left bytes from the end of buf->buf to the beginning first. If EOF is reached and the file wasn't terminated by a newline, supply one. Return a count of bytes buffered. */ static int fillbuf (struct buffer *buf, FILE *fp) { int cc; memmove (buf->buf, buf->buf + buf->used - buf->left, buf->left); buf->used = buf->left; while (!feof (fp) && (buf->used == 0 || !memchr (buf->buf, '\n', buf->used))) { if (buf->used == buf->alloc) { buf->alloc *= 2; buf->buf = xrealloc (buf->buf, buf->alloc); } cc = fread (buf->buf + buf->used, 1, buf->alloc - buf->used, fp); if (ferror (fp)) { error (0, errno, _("read error")); cleanup (); exit (2); } buf->used += cc; } if (feof (fp) && buf->used && buf->buf[buf->used - 1] != '\n') { if (buf->used == buf->alloc) { buf->alloc *= 2; buf->buf = xrealloc (buf->buf, buf->alloc); } buf->buf[buf->used++] = '\n'; } return buf->used; } /* Initialize LINES, allocating space for ALLOC lines initially. LIMIT is the maximum possible number of lines to allocate space for, ever. */ static void initlines (struct lines *lines, int alloc, int limit) { lines->alloc = alloc; lines->lines = (struct line *) xmalloc (lines->alloc * sizeof (struct line)); lines->used = 0; lines->limit = limit; } /* Return a pointer to the first character of the field specified by KEY in LINE. */ static char * begfield (const struct line *line, const struct keyfield *key) { register char *ptr = line->text, *lim = ptr + line->length; register int sword = key->sword, schar = key->schar; if (tab) while (ptr < lim && sword--) { while (ptr < lim && *ptr != tab) ++ptr; if (ptr < lim) ++ptr; } else while (ptr < lim && sword--) { while (ptr < lim && blanks[UCHAR (*ptr)]) ++ptr; while (ptr < lim && !blanks[UCHAR (*ptr)]) ++ptr; } if (key->skipsblanks) while (ptr < lim && blanks[UCHAR (*ptr)]) ++ptr; if (ptr + schar <= lim) ptr += schar; else ptr = lim; return ptr; } /* Return the limit of (a pointer to the first character after) the field in LINE specified by KEY. */ static char * limfield (const struct line *line, const struct keyfield *key) { register char *ptr = line->text, *lim = ptr + line->length; register int eword = key->eword, echar = key->echar; /* Note: from the POSIX spec: The leading field separator itself is included in a field when -t is not used. FIXME: move this comment up... */ /* Move PTR past EWORD fields or to one past the last byte on LINE, whichever comes first. If there are more than EWORD fields, leave PTR pointing at the beginning of the field having zero-based index, EWORD. If a delimiter character was specified (via -t), then that `beginning' is the first character following the delimiting TAB. Otherwise, leave PTR pointing at the first `blank' character after the preceding field. */ if (tab) while (ptr < lim && eword--) { while (ptr < lim && *ptr != tab) ++ptr; if (ptr < lim && (eword || echar > 0)) ++ptr; } else while (ptr < lim && eword--) { while (ptr < lim && blanks[UCHAR (*ptr)]) ++ptr; while (ptr < lim && !blanks[UCHAR (*ptr)]) ++ptr; } /* Make LIM point to the end of (one byte past) the current field. */ if (tab) { char *newlim; newlim = memchr (ptr, tab, lim - ptr); if (newlim) lim = newlim; } else { char *newlim; newlim = ptr; while (newlim < lim && blanks[UCHAR (*newlim)]) ++newlim; while (newlim < lim && !blanks[UCHAR (*newlim)]) ++newlim; lim = newlim; } /* If we're skipping leading blanks, don't start counting characters until after skipping past any leading blanks. */ if (key->skipsblanks) while (ptr < lim && blanks[UCHAR (*ptr)]) ++ptr; /* Advance PTR by ECHAR (if possible), but no further than LIM. */ if (ptr + echar <= lim) ptr += echar; else ptr = lim; return ptr; } /* FIXME */ void trim_trailing_blanks (const char *a_start, char **a_end) { while (*a_end > a_start && blanks[UCHAR (*(*a_end - 1))]) --(*a_end); } /* Find the lines in BUF, storing pointers and lengths in LINES. Also replace newlines in BUF with NULs. */ static void findlines (struct buffer *buf, struct lines *lines) { register char *beg = buf->buf, *lim = buf->buf + buf->used, *ptr; struct keyfield *key = keyhead.next; lines->used = 0; while (beg < lim && (ptr = memchr (beg, '\n', lim - beg)) && lines->used < lines->limit) { /* There are various places in the code that rely on a NUL being at the end of in-core lines; NULs inside the lines will not cause trouble, though. */ *ptr = '\0'; if (lines->used == lines->alloc) { lines->alloc *= 2; lines->lines = (struct line *) xrealloc ((char *) lines->lines, lines->alloc * sizeof (struct line)); } lines->lines[lines->used].text = beg; lines->lines[lines->used].length = ptr - beg; /* Precompute the position of the first key for efficiency. */ if (key) { if (key->eword >= 0) lines->lines[lines->used].keylim = limfield (&lines->lines[lines->used], key); else lines->lines[lines->used].keylim = ptr; if (key->sword >= 0) lines->lines[lines->used].keybeg = begfield (&lines->lines[lines->used], key); else { if (key->skipsblanks) while (blanks[UCHAR (*beg)]) ++beg; lines->lines[lines->used].keybeg = beg; } if (key->skipeblanks) { trim_trailing_blanks (lines->lines[lines->used].keybeg, &lines->lines[lines->used].keylim); } } else { lines->lines[lines->used].keybeg = 0; lines->lines[lines->used].keylim = 0; } ++lines->used; beg = ptr + 1; } buf->left = lim - beg; } /* Compare strings A and B containing decimal fractions < 1. Each string should begin with a decimal point followed immediately by the digits of the fraction. Strings not of this form are considered to be zero. */ static int fraccompare (register const char *a, register const char *b) { register tmpa = UCHAR (*a), tmpb = UCHAR (*b); #ifdef __DragonFly__ if (tmpa == decimal_point && tmpb == decimal_point) #else if (tmpa == '.' && tmpb == '.') #endif { do tmpa = UCHAR (*++a), tmpb = UCHAR (*++b); while (tmpa == tmpb && digits[tmpa]); if (digits[tmpa] && digits[tmpb]) return tmpa - tmpb; if (digits[tmpa]) { while (tmpa == '0') tmpa = UCHAR (*++a); if (digits[tmpa]) return 1; return 0; } if (digits[tmpb]) { while (tmpb == '0') tmpb = UCHAR (*++b); if (digits[tmpb]) return -1; return 0; } return 0; } #ifdef __DragonFly__ else if (tmpa == decimal_point) #else else if (tmpa == '.') #endif { do tmpa = UCHAR (*++a); while (tmpa == '0'); if (digits[tmpa]) return 1; return 0; } #ifdef __DragonFly__ else if (tmpb == decimal_point) #else else if (tmpb == '.') #endif { do tmpb = UCHAR (*++b); while (tmpb == '0'); if (digits[tmpb]) return -1; return 0; } return 0; } /* Compare strings A and B as numbers without explicitly converting them to machine numbers. Comparatively slow for short strings, but asymptotically hideously fast. */ static int numcompare (register const char *a, register const char *b) { register int tmpa, tmpb, loga, logb, tmp; tmpa = UCHAR (*a); tmpb = UCHAR (*b); while (blanks[tmpa]) tmpa = UCHAR (*++a); while (blanks[tmpb]) tmpb = UCHAR (*++b); if (tmpa == '-') { do tmpa = UCHAR (*++a); while (tmpa == '0'); if (tmpb != '-') { #ifdef __DragonFly__ if (tmpa == decimal_point) #else if (tmpa == '.') #endif do tmpa = UCHAR (*++a); while (tmpa == '0'); if (digits[tmpa]) return -1; while (tmpb == '0') tmpb = UCHAR (*++b); #ifdef __DragonFly__ if (tmpb == decimal_point) #else if (tmpb == '.') #endif do tmpb = UCHAR (*++b); while (tmpb == '0'); if (digits[tmpb]) return -1; return 0; } do tmpb = UCHAR (*++b); while (tmpb == '0'); while (tmpa == tmpb && digits[tmpa]) tmpa = UCHAR (*++a), tmpb = UCHAR (*++b); #ifdef __DragonFly__ if ((tmpa == decimal_point && !digits[tmpb]) || (tmpb == decimal_point && !digits[tmpa])) #else if ((tmpa == '.' && !digits[tmpb]) || (tmpb == '.' && !digits[tmpa])) #endif return -fraccompare (a, b); if (digits[tmpa]) for (loga = 1; digits[UCHAR (*++a)]; ++loga) ; else loga = 0; if (digits[tmpb]) for (logb = 1; digits[UCHAR (*++b)]; ++logb) ; else logb = 0; if ((tmp = logb - loga) != 0) return tmp; if (!loga) return 0; #ifdef __DragonFly__ return COLLDIFF (tmpb, tmpa); #else return tmpb - tmpa; #endif } else if (tmpb == '-') { do tmpb = UCHAR (*++b); while (tmpb == '0'); #ifdef __DragonFly__ if (tmpb == decimal_point) #else if (tmpb == '.') #endif do tmpb = UCHAR (*++b); while (tmpb == '0'); if (digits[tmpb]) return 1; while (tmpa == '0') tmpa = UCHAR (*++a); #ifdef __DragonFly__ if (tmpa == decimal_point) #else if (tmpa == '.') #endif do tmpa = UCHAR (*++a); while (tmpa == '0'); if (digits[tmpa]) return 1; return 0; } else { while (tmpa == '0') tmpa = UCHAR (*++a); while (tmpb == '0') tmpb = UCHAR (*++b); while (tmpa == tmpb && digits[tmpa]) tmpa = UCHAR (*++a), tmpb = UCHAR (*++b); #ifdef __DragonFly__ if ((tmpa == decimal_point && !digits[tmpb]) || (tmpb == decimal_point && !digits[tmpa])) #else if ((tmpa == '.' && !digits[tmpb]) || (tmpb == '.' && !digits[tmpa])) #endif return fraccompare (a, b); if (digits[tmpa]) for (loga = 1; digits[UCHAR (*++a)]; ++loga) ; else loga = 0; if (digits[tmpb]) for (logb = 1; digits[UCHAR (*++b)]; ++logb) ; else logb = 0; if ((tmp = loga - logb) != 0) return tmp; if (!loga) return 0; #ifdef __DragonFly__ return COLLDIFF (tmpa, tmpb); #else return tmpa - tmpb; #endif } } static int general_numcompare (const char *sa, const char *sb) { double a, b; /* FIXME: add option to warn about failed conversions. */ /* FIXME: maybe add option to try expensive FP conversion only if A and B can't be compared more cheaply/accurately. */ if (xstrtod (sa, NULL, &a)) { a = 0; } if (xstrtod (sb, NULL, &b)) { b = 0; } return a == b ? 0 : a < b ? -1 : 1; } /* Return an integer <= 12 associated with month name S with length LEN, 0 if the name in S is not recognized. */ static int getmonth (const char *s, int len) { char month[4]; register int i, lo = 0, hi = 12; while (len > 0 && blanks[UCHAR(*s)]) ++s, --len; if (len < 3) return 0; for (i = 0; i < 3; ++i) month[i] = fold_toupper[UCHAR (s[i])]; month[3] = '\0'; while (hi - lo > 1) if (strcmp (month, monthtab[(lo + hi) / 2].name) < 0) hi = (lo + hi) / 2; else lo = (lo + hi) / 2; if (!strcmp (month, monthtab[lo].name)) return monthtab[lo].val; return 0; } /* Compare two lines A and B trying every key in sequence until there are no more keys or a difference is found. */ static int keycompare (const struct line *a, const struct line *b) { register char *texta, *textb, *lima, *limb, *translate; register int *ignore; struct keyfield *key; int diff = 0, iter = 0, lena, lenb; for (key = keyhead.next; key; key = key->next, ++iter) { ignore = key->ignore; translate = key->translate; /* Find the beginning and limit of each field. */ if (iter || a->keybeg == NULL || b->keybeg == NULL) { if (key->eword >= 0) lima = limfield (a, key), limb = limfield (b, key); else lima = a->text + a->length, limb = b->text + b->length; if (key->sword >= 0) texta = begfield (a, key), textb = begfield (b, key); else { texta = a->text, textb = b->text; if (key->skipsblanks) { while (texta < lima && blanks[UCHAR (*texta)]) ++texta; while (textb < limb && blanks[UCHAR (*textb)]) ++textb; } } } else { /* For the first iteration only, the key positions have been precomputed for us. */ texta = a->keybeg, lima = a->keylim; textb = b->keybeg, limb = b->keylim; } /* Find the lengths. */ lena = lima - texta, lenb = limb - textb; if (lena < 0) lena = 0; if (lenb < 0) lenb = 0; if (key->skipeblanks) { char *a_end = texta + lena; char *b_end = textb + lenb; trim_trailing_blanks (texta, &a_end); trim_trailing_blanks (textb, &b_end); lena = a_end - texta; lenb = b_end - textb; } /* Actually compare the fields. */ if (key->numeric) { if (*lima || *limb) { char savea = *lima, saveb = *limb; *lima = *limb = '\0'; diff = numcompare (texta, textb); *lima = savea, *limb = saveb; } else diff = numcompare (texta, textb); if (diff) return key->reverse ? -diff : diff; continue; } else if (key->general_numeric) { if (*lima || *limb) { char savea = *lima, saveb = *limb; *lima = *limb = '\0'; diff = general_numcompare (texta, textb); *lima = savea, *limb = saveb; } else diff = general_numcompare (texta, textb); if (diff) return key->reverse ? -diff : diff; continue; } else if (key->month) { diff = getmonth (texta, lena) - getmonth (textb, lenb); if (diff) return key->reverse ? -diff : diff; continue; } else if (ignore && translate) #ifdef __DragonFly__ #define CMP_FUNC(A, B) COLLDIFF ((A), (B)) #else #define CMP_FUNC(A, B) (A) - (B) #endif #define CMP_WITH_IGNORE(A, B) \ do \ { \ while (texta < lima && textb < limb) \ { \ while (texta < lima && ignore[UCHAR (*texta)]) \ ++texta; \ while (textb < limb && ignore[UCHAR (*textb)]) \ ++textb; \ if (texta < lima && textb < limb) \ { \ if ((A) != (B)) \ { \ diff = CMP_FUNC((A), (B)); \ break; \ } \ ++texta; \ ++textb; \ } \ \ if (texta == lima && textb < limb && !ignore[UCHAR (*textb)]) \ diff = -1; \ else if (texta < lima && textb == limb \ && !ignore[UCHAR (*texta)]) \ diff = 1; \ } \ \ if (diff == 0) \ { \ while (texta < lima && ignore[UCHAR (*texta)]) \ ++texta; \ while (textb < limb && ignore[UCHAR (*textb)]) \ ++textb; \ \ if (texta == lima && textb < limb) \ diff = -1; \ else if (texta < lima && textb == limb) \ diff = 1; \ } \ /* Relative lengths are meaningless if characters were ignored. \ Handling this case here avoids what might be an invalid length \ comparison below. */ \ if (diff == 0 && texta == lima && textb == limb) \ return 0; \ } \ while (0) CMP_WITH_IGNORE (translate[UCHAR (*texta)], translate[UCHAR (*textb)]); else if (ignore) CMP_WITH_IGNORE (*texta, *textb); else if (translate) while (texta < lima && textb < limb) { if (translate[UCHAR (*texta++)] != translate[UCHAR (*textb++)]) { #ifdef __DragonFly__ diff = COLLDIFF (translate[UCHAR (*--texta)], translate[UCHAR (*--textb)]); #else diff = (translate[UCHAR (*--texta)] - translate[UCHAR (*--textb)]); #endif break; } } else #ifdef __DragonFly__ diff = collcmp (texta, textb, min (lena, lenb)); #else diff = memcmp (texta, textb, min (lena, lenb)); #endif if (diff) return key->reverse ? -diff : diff; if ((diff = lena - lenb) != 0) return key->reverse ? -diff : diff; } return 0; } /* Compare two lines A and B, returning negative, zero, or positive depending on whether A compares less than, equal to, or greater than B. */ static int compare (register const struct line *a, register const struct line *b) { int diff, tmpa, tmpb, mini; /* First try to compare on the specified keys (if any). The only two cases with no key at all are unadorned sort, and unadorned sort -r. */ if (keyhead.next) { diff = keycompare (a, b); if (diff != 0) return diff; if (unique || stable) return 0; } /* If the keys all compare equal (or no keys were specified) fall through to the default byte-by-byte comparison. */ tmpa = a->length, tmpb = b->length; mini = min (tmpa, tmpb); if (mini == 0) diff = tmpa - tmpb; else { char *ap = a->text, *bp = b->text; #ifndef __DragonFly__ diff = UCHAR (*ap) - UCHAR (*bp); if (diff == 0) { #endif #ifdef __DragonFly__ diff = collcmp (ap, bp, mini); #else diff = memcmp (ap, bp, mini); #endif if (diff == 0) diff = tmpa - tmpb; #ifndef __DragonFly__ } #endif } return reverse ? -diff : diff; } /* Check that the lines read from the given FP come in order. Return 1 if they do and 0 if there is a disorder. FIXME: return number of first out-of-order line if not sorted. */ static int checkfp (FILE *fp) { struct buffer buf; /* Input buffer. */ struct lines lines; /* Lines scanned from the buffer. */ struct line temp; /* Copy of previous line. */ int cc; /* Character count. */ int alloc, sorted = 1; initbuf (&buf, mergealloc); initlines (&lines, mergealloc / linelength + 1, LINEALLOC / ((NMERGE + NMERGE) * sizeof (struct line))); alloc = linelength; temp.text = xmalloc (alloc); cc = fillbuf (&buf, fp); if (cc == 0) goto finish; findlines (&buf, &lines); while (1) { struct line *prev_line; /* Pointer to previous line. */ int cmp; /* Result of calling compare. */ int i; /* Compare each line in the buffer with its successor. */ for (i = 0; i < lines.used - 1; ++i) { cmp = compare (&lines.lines[i], &lines.lines[i + 1]); if ((unique && cmp >= 0) || (cmp > 0)) { sorted = 0; goto finish; } } /* Save the last line of the buffer and refill the buffer. */ prev_line = lines.lines + (lines.used - 1); if (prev_line->length > alloc) { while (prev_line->length + 1 > alloc) alloc *= 2; temp.text = xrealloc (temp.text, alloc); } memcpy (temp.text, prev_line->text, prev_line->length + 1); temp.length = prev_line->length; temp.keybeg = temp.text + (prev_line->keybeg - prev_line->text); temp.keylim = temp.text + (prev_line->keylim - prev_line->text); cc = fillbuf (&buf, fp); if (cc == 0) break; findlines (&buf, &lines); /* Make sure the line saved from the old buffer contents is less than or equal to the first line of the new buffer. */ cmp = compare (&temp, &lines.lines[0]); if ((unique && cmp >= 0) || (cmp > 0)) { sorted = 0; break; } } finish: xfclose (fp); free (buf.buf); free ((char *) lines.lines); free (temp.text); return sorted; } /* Merge lines from FPS onto OFP. NFPS cannot be greater than NMERGE. Close FPS before returning. */ static void mergefps (FILE **fps, register int nfps, FILE *ofp) { struct buffer buffer[NMERGE]; /* Input buffers for each file. */ struct lines lines[NMERGE]; /* Line tables for each buffer. */ struct line saved; /* Saved line for unique check. */ int savedflag = 0; /* True if there is a saved line. */ int savealloc; /* Size allocated for the saved line. */ int cur[NMERGE]; /* Current line in each line table. */ int ord[NMERGE]; /* Table representing a permutation of fps, such that lines[ord[0]].lines[cur[ord[0]]] is the smallest line and will be next output. */ register int i, j, t; #ifdef lint /* Suppress `used before initialized' warning. */ savealloc = 0; #endif /* Allocate space for a saved line if necessary. */ if (unique) { savealloc = linelength; saved.text = xmalloc (savealloc); } /* Read initial lines from each input file. */ for (i = 0; i < nfps; ++i) { initbuf (&buffer[i], mergealloc); /* If a file is empty, eliminate it from future consideration. */ while (i < nfps && !fillbuf (&buffer[i], fps[i])) { xfclose (fps[i]); --nfps; for (j = i; j < nfps; ++j) fps[j] = fps[j + 1]; } if (i == nfps) free (buffer[i].buf); else { initlines (&lines[i], mergealloc / linelength + 1, LINEALLOC / ((NMERGE + NMERGE) * sizeof (struct line))); findlines (&buffer[i], &lines[i]); cur[i] = 0; } } /* Set up the ord table according to comparisons among input lines. Since this only reorders two items if one is strictly greater than the other, it is stable. */ for (i = 0; i < nfps; ++i) ord[i] = i; for (i = 1; i < nfps; ++i) if (compare (&lines[ord[i - 1]].lines[cur[ord[i - 1]]], &lines[ord[i]].lines[cur[ord[i]]]) > 0) t = ord[i - 1], ord[i - 1] = ord[i], ord[i] = t, i = 0; /* Repeatedly output the smallest line until no input remains. */ while (nfps) { /* If uniqified output is turned on, output only the first of an identical series of lines. */ if (unique) { if (savedflag && compare (&saved, &lines[ord[0]].lines[cur[ord[0]]])) { xfwrite (saved.text, 1, saved.length, ofp); putc ('\n', ofp); savedflag = 0; } if (!savedflag) { if (savealloc < lines[ord[0]].lines[cur[ord[0]]].length + 1) { while (savealloc < lines[ord[0]].lines[cur[ord[0]]].length + 1) savealloc *= 2; saved.text = xrealloc (saved.text, savealloc); } saved.length = lines[ord[0]].lines[cur[ord[0]]].length; memcpy (saved.text, lines[ord[0]].lines[cur[ord[0]]].text, saved.length + 1); if (lines[ord[0]].lines[cur[ord[0]]].keybeg != NULL) { saved.keybeg = saved.text + (lines[ord[0]].lines[cur[ord[0]]].keybeg - lines[ord[0]].lines[cur[ord[0]]].text); } if (lines[ord[0]].lines[cur[ord[0]]].keylim != NULL) { saved.keylim = saved.text + (lines[ord[0]].lines[cur[ord[0]]].keylim - lines[ord[0]].lines[cur[ord[0]]].text); } savedflag = 1; } } else { xfwrite (lines[ord[0]].lines[cur[ord[0]]].text, 1, lines[ord[0]].lines[cur[ord[0]]].length, ofp); putc ('\n', ofp); } /* Check if we need to read more lines into core. */ if (++cur[ord[0]] == lines[ord[0]].used) if (fillbuf (&buffer[ord[0]], fps[ord[0]])) { findlines (&buffer[ord[0]], &lines[ord[0]]); cur[ord[0]] = 0; } else { /* We reached EOF on fps[ord[0]]. */ for (i = 1; i < nfps; ++i) if (ord[i] > ord[0]) --ord[i]; --nfps; xfclose (fps[ord[0]]); free (buffer[ord[0]].buf); free ((char *) lines[ord[0]].lines); for (i = ord[0]; i < nfps; ++i) { fps[i] = fps[i + 1]; buffer[i] = buffer[i + 1]; lines[i] = lines[i + 1]; cur[i] = cur[i + 1]; } for (i = 0; i < nfps; ++i) ord[i] = ord[i + 1]; continue; } /* The new line just read in may be larger than other lines already in core; push it back in the queue until we encounter a line larger than it. */ for (i = 1; i < nfps; ++i) { t = compare (&lines[ord[0]].lines[cur[ord[0]]], &lines[ord[i]].lines[cur[ord[i]]]); if (!t) t = ord[0] - ord[i]; if (t < 0) break; } t = ord[0]; for (j = 1; j < i; ++j) ord[j - 1] = ord[j]; ord[i - 1] = t; } if (unique && savedflag) { xfwrite (saved.text, 1, saved.length, ofp); putc ('\n', ofp); free (saved.text); } } /* Sort the array LINES with NLINES members, using TEMP for temporary space. */ static void sortlines (struct line *lines, int nlines, struct line *temp) { register struct line *lo, *hi, *t; register int nlo, nhi; if (nlines == 2) { if (compare (&lines[0], &lines[1]) > 0) *temp = lines[0], lines[0] = lines[1], lines[1] = *temp; return; } nlo = nlines / 2; lo = lines; nhi = nlines - nlo; hi = lines + nlo; if (nlo > 1) sortlines (lo, nlo, temp); if (nhi > 1) sortlines (hi, nhi, temp); t = temp; while (nlo && nhi) if (compare (lo, hi) <= 0) *t++ = *lo++, --nlo; else *t++ = *hi++, --nhi; while (nlo--) *t++ = *lo++; for (lo = lines, nlo = nlines - nhi, t = temp; nlo; --nlo) *lo++ = *t++; } /* Check that each of the NFILES FILES is ordered. Return a count of disordered files. */ static int check (char **files, int nfiles) { int i, disorders = 0; FILE *fp; for (i = 0; i < nfiles; ++i) { fp = xfopen (files[i], "r"); if (!checkfp (fp)) { fprintf (stderr, _("%s: disorder on %s\n"), program_name, files[i]); ++disorders; } } return disorders; } /* Merge NFILES FILES onto OFP. */ static void merge (char **files, int nfiles, FILE *ofp) { int i, j, t; char *temp; FILE *fps[NMERGE], *tfp; while (nfiles > NMERGE) { t = 0; for (i = 0; i < nfiles / NMERGE; ++i) { for (j = 0; j < NMERGE; ++j) fps[j] = xfopen (files[i * NMERGE + j], "r"); tfp = xtmpfopen (temp = tempname ()); mergefps (fps, NMERGE, tfp); xfclose (tfp); for (j = 0; j < NMERGE; ++j) zaptemp (files[i * NMERGE + j]); files[t++] = temp; } for (j = 0; j < nfiles % NMERGE; ++j) fps[j] = xfopen (files[i * NMERGE + j], "r"); tfp = xtmpfopen (temp = tempname ()); mergefps (fps, nfiles % NMERGE, tfp); xfclose (tfp); for (j = 0; j < nfiles % NMERGE; ++j) zaptemp (files[i * NMERGE + j]); files[t++] = temp; nfiles = t; } for (i = 0; i < nfiles; ++i) fps[i] = xfopen (files[i], "r"); mergefps (fps, i, ofp); for (i = 0; i < nfiles; ++i) zaptemp (files[i]); } /* Sort NFILES FILES onto OFP. */ static void sort (char **files, int nfiles, FILE *ofp) { struct buffer buf; struct lines lines; struct line *tmp; int i, ntmp; FILE *fp, *tfp; struct tempnode *node; int n_temp_files = 0; char **tempfiles; initbuf (&buf, sortalloc); initlines (&lines, sortalloc / linelength + 1, LINEALLOC / sizeof (struct line)); ntmp = lines.alloc; tmp = (struct line *) xmalloc (ntmp * sizeof (struct line)); while (nfiles--) { fp = xfopen (*files++, "r"); while (fillbuf (&buf, fp)) { findlines (&buf, &lines); if (lines.used > ntmp) { while (lines.used > ntmp) ntmp *= 2; tmp = (struct line *) xrealloc ((char *) tmp, ntmp * sizeof (struct line)); } sortlines (lines.lines, lines.used, tmp); if (feof (fp) && !nfiles && !n_temp_files && !buf.left) tfp = ofp; else { ++n_temp_files; tfp = xtmpfopen (tempname ()); } for (i = 0; i < lines.used; ++i) if (!unique || i == 0 || compare (&lines.lines[i], &lines.lines[i - 1])) { xfwrite (lines.lines[i].text, 1, lines.lines[i].length, tfp); putc ('\n', tfp); } if (tfp != ofp) xfclose (tfp); } xfclose (fp); } free (buf.buf); free ((char *) lines.lines); free ((char *) tmp); if (n_temp_files) { tempfiles = (char **) xmalloc (n_temp_files * sizeof (char *)); i = n_temp_files; for (node = temphead.next; i > 0; node = node->next) tempfiles[--i] = node->name; merge (tempfiles, n_temp_files, ofp); free ((char *) tempfiles); } } /* Insert key KEY at the end of the list (`keyhead'). */ static void insertkey (struct keyfield *key) { struct keyfield *k = &keyhead; while (k->next) k = k->next; k->next = key; key->next = NULL; } static void badfieldspec (const char *s) { error (2, 0, _("invalid field specification `%s'"), s); } /* Handle interrupts and hangups. */ static void sighandler (int sig) { #ifdef SA_INTERRUPT struct sigaction sigact; sigact.sa_handler = SIG_DFL; sigemptyset (&sigact.sa_mask); sigact.sa_flags = 0; sigaction (sig, &sigact, NULL); #else /* !SA_INTERRUPT */ signal (sig, SIG_DFL); #endif /* SA_INTERRUPT */ cleanup (); kill (getpid (), sig); } /* Set the ordering options for KEY specified in S. Return the address of the first character in S that is not a valid ordering option. BLANKTYPE is the kind of blanks that 'b' should skip. */ static char * set_ordering (register const char *s, struct keyfield *key, enum blanktype blanktype) { while (*s) { switch (*s) { case 'b': if (blanktype == bl_start || blanktype == bl_both) key->skipsblanks = 1; if (blanktype == bl_end || blanktype == bl_both) key->skipeblanks = 1; break; case 'd': key->ignore = nondictionary; break; case 'f': key->translate = fold_toupper; break; case 'g': key->general_numeric = 1; break; case 'i': key->ignore = nonprinting; break; case 'M': key->month = 1; break; case 'n': key->numeric = 1; if (blanktype == bl_start || blanktype == bl_both) key->skipsblanks = 1; if (blanktype == bl_end || blanktype == bl_both) key->skipeblanks = 1; break; case 'r': key->reverse = 1; break; default: return (char *) s; } ++s; } return (char *) s; } int main (int argc, char **argv) { struct keyfield *key = NULL, gkey; char *s; int i, t, t2; int checkonly = 0, mergeonly = 0, nfiles = 0; char *minus = "-", *outfile = minus, **files, *tmp; FILE *ofp; #ifdef SA_INTERRUPT struct sigaction oldact, newact; #endif /* SA_INTERRUPT */ #ifdef __DragonFly__ (void) setlocale(LC_ALL, ""); decimal_point = localeconv()->decimal_point[0]; #endif program_name = argv[0]; parse_long_options (argc, argv, "sort", version_string, usage); have_read_stdin = 0; inittables (); temp_file_prefix = getenv ("TMPDIR"); if (temp_file_prefix == NULL) temp_file_prefix = DEFAULT_TMPDIR; #ifdef SA_INTERRUPT newact.sa_handler = sighandler; sigemptyset (&newact.sa_mask); newact.sa_flags = 0; sigaction (SIGINT, NULL, &oldact); if (oldact.sa_handler != SIG_IGN) sigaction (SIGINT, &newact, NULL); sigaction (SIGHUP, NULL, &oldact); if (oldact.sa_handler != SIG_IGN) sigaction (SIGHUP, &newact, NULL); sigaction (SIGPIPE, NULL, &oldact); if (oldact.sa_handler != SIG_IGN) sigaction (SIGPIPE, &newact, NULL); sigaction (SIGTERM, NULL, &oldact); if (oldact.sa_handler != SIG_IGN) sigaction (SIGTERM, &newact, NULL); #else /* !SA_INTERRUPT */ if (signal (SIGINT, SIG_IGN) != SIG_IGN) signal (SIGINT, sighandler); if (signal (SIGHUP, SIG_IGN) != SIG_IGN) signal (SIGHUP, sighandler); if (signal (SIGPIPE, SIG_IGN) != SIG_IGN) signal (SIGPIPE, sighandler); if (signal (SIGTERM, SIG_IGN) != SIG_IGN) signal (SIGTERM, sighandler); #endif /* !SA_INTERRUPT */ gkey.sword = gkey.eword = -1; gkey.ignore = NULL; gkey.translate = NULL; gkey.numeric = gkey.general_numeric = gkey.month = gkey.reverse = 0; gkey.skipsblanks = gkey.skipeblanks = 0; files = (char **) xmalloc (sizeof (char *) * argc); for (i = 1; i < argc; ++i) { if (argv[i][0] == '+') { if (key) insertkey (key); key = (struct keyfield *) xmalloc (sizeof (struct keyfield)); key->eword = -1; key->ignore = NULL; key->translate = NULL; key->skipsblanks = key->skipeblanks = 0; key->numeric = key->general_numeric = key->month = key->reverse = 0; s = argv[i] + 1; if (! (digits[UCHAR (*s)] || (*s == '.' && digits[UCHAR (s[1])]))) badfieldspec (argv[i]); for (t = 0; digits[UCHAR (*s)]; ++s) t = 10 * t + *s - '0'; t2 = 0; if (*s == '.') for (++s; digits[UCHAR (*s)]; ++s) t2 = 10 * t2 + *s - '0'; if (t2 || t) { key->sword = t; key->schar = t2; } else key->sword = -1; s = set_ordering (s, key, bl_start); if (*s) badfieldspec (argv[i]); } else if (argv[i][0] == '-' && argv[i][1]) { s = argv[i] + 1; if (digits[UCHAR (*s)] || (*s == '.' && digits[UCHAR (s[1])])) { if (!key) usage (2); for (t = 0; digits[UCHAR (*s)]; ++s) t = t * 10 + *s - '0'; t2 = 0; if (*s == '.') for (++s; digits[UCHAR (*s)]; ++s) t2 = t2 * 10 + *s - '0'; key->eword = t; key->echar = t2; s = set_ordering (s, key, bl_end); if (*s) badfieldspec (argv[i]); insertkey (key); key = NULL; } else while (*s) { s = set_ordering (s, &gkey, bl_both); switch (*s) { case '\0': break; case 'c': checkonly = 1; break; case 'k': if (s[1]) ++s; else { if (i == argc - 1) error (2, 0, _("option `-k' requires an argument")); else s = argv[++i]; } if (key) insertkey (key); key = (struct keyfield *) xmalloc (sizeof (struct keyfield)); memset (key, 0, sizeof (struct keyfield)); key->eword = -1; key->ignore = NULL; key->translate = NULL; key->skipsblanks = key->skipeblanks = 0; key->numeric = key->month = key->reverse = 0; /* Get POS1. */ if (!digits[UCHAR (*s)]) badfieldspec (argv[i]); for (t = 0; digits[UCHAR (*s)]; ++s) t = 10 * t + *s - '0'; if (t == 0) { /* Provoke with `sort -k0' */ error (0, 0, _("the starting field number argument \ to the `-k' option must be positive")); badfieldspec (argv[i]); } --t; t2 = 0; if (*s == '.') { if (!digits[UCHAR (s[1])]) { /* Provoke with `sort -k1.' */ error (0, 0, _("starting field spec has `.' but \ lacks following character offset")); badfieldspec (argv[i]); } for (++s; digits[UCHAR (*s)]; ++s) t2 = 10 * t2 + *s - '0'; if (t2 == 0) { /* Provoke with `sort -k1.0' */ error (0, 0, _("starting field character offset \ argument to the `-k' option\nmust be positive")); badfieldspec (argv[i]); } --t2; } if (t2 || t) { key->sword = t; key->schar = t2; } else key->sword = -1; s = set_ordering (s, key, bl_start); if (*s == 0) { key->eword = -1; key->echar = 0; } else if (*s != ',') badfieldspec (argv[i]); else if (*s == ',') { /* Skip over comma. */ ++s; if (*s == 0) { /* Provoke with `sort -k1,' */ error (0, 0, _("field specification has `,' but \ lacks following field spec")); badfieldspec (argv[i]); } /* Get POS2. */ for (t = 0; digits[UCHAR (*s)]; ++s) t = t * 10 + *s - '0'; if (t == 0) { /* Provoke with `sort -k1,0' */ error (0, 0, _("ending field number argument \ to the `-k' option must be positive")); badfieldspec (argv[i]); } --t; t2 = 0; if (*s == '.') { if (!digits[UCHAR (s[1])]) { /* Provoke with `sort -k1,1.' */ error (0, 0, _("ending field spec has `.' \ but lacks following character offset")); badfieldspec (argv[i]); } for (++s; digits[UCHAR (*s)]; ++s) t2 = t2 * 10 + *s - '0'; } else { /* `-k 2,3' is equivalent to `+1 -3'. */ ++t; } key->eword = t; key->echar = t2; s = set_ordering (s, key, bl_end); if (*s) badfieldspec (argv[i]); } insertkey (key); key = NULL; goto outer; case 'm': mergeonly = 1; break; case 'o': if (s[1]) outfile = s + 1; else { if (i == argc - 1) error (2, 0, _("option `-o' requires an argument")); else outfile = argv[++i]; } goto outer; case 's': stable = 1; break; case 't': if (s[1]) tab = *++s; else if (i < argc - 1) { tab = *argv[++i]; goto outer; } else error (2, 0, _("option `-t' requires an argument")); break; case 'T': if (s[1]) temp_file_prefix = ++s; else { if (i < argc - 1) temp_file_prefix = argv[++i]; else error (2, 0, _("option `-T' requires an argument")); } goto outer; /* break; */ case 'u': unique = 1; break; case 'y': /* Accept and ignore e.g. -y0 for compatibility with Solaris 2. */ goto outer; default: fprintf (stderr, _("%s: unrecognized option `-%c'\n"), argv[0], *s); usage (2); } if (*s) ++s; } } else /* Not an option. */ { files[nfiles++] = argv[i]; } outer:; } if (key) insertkey (key); /* Inheritance of global options to individual keys. */ for (key = keyhead.next; key; key = key->next) if (!key->ignore && !key->translate && !key->skipsblanks && !key->reverse && !key->skipeblanks && !key->month && !key->numeric && !key->general_numeric) { key->ignore = gkey.ignore; key->translate = gkey.translate; key->skipsblanks = gkey.skipsblanks; key->skipeblanks = gkey.skipeblanks; key->month = gkey.month; key->numeric = gkey.numeric; key->general_numeric = gkey.general_numeric; key->reverse = gkey.reverse; } if (!keyhead.next && (gkey.ignore || gkey.translate || gkey.skipsblanks || gkey.skipeblanks || gkey.month || gkey.numeric || gkey.general_numeric)) insertkey (&gkey); reverse = gkey.reverse; if (nfiles == 0) { nfiles = 1; files = − } if (checkonly) exit (check (files, nfiles) != 0); if (strcmp (outfile, "-")) { struct stat outstat; if (stat (outfile, &outstat) == 0) { /* The following code prevents a race condition when people use the brain dead shell programming idiom: cat file | sort -o file This feature is provided for historical compatibility, but we strongly discourage ever relying on this in new shell programs. */ /* Temporarily copy each input file that might be another name for the output file. When in doubt (e.g. a pipe), copy. */ for (i = 0; i < nfiles; ++i) { char buf[8192]; FILE *fp; int cc; if (S_ISREG (outstat.st_mode) && strcmp (outfile, files[i])) { struct stat instat; if ((strcmp (files[i], "-") ? stat (files[i], &instat) : fstat (fileno (stdin), &instat)) != 0) { error (0, errno, "%s", files[i]); cleanup (); exit (2); } if (S_ISREG (instat.st_mode) && (instat.st_ino != outstat.st_ino || instat.st_dev != outstat.st_dev)) { /* We know the files are distinct. */ continue; } } fp = xfopen (files[i], "r"); tmp = tempname (); ofp = xtmpfopen (tmp); while ((cc = fread (buf, 1, sizeof buf, fp)) > 0) xfwrite (buf, 1, cc, ofp); if (ferror (fp)) { error (0, errno, "%s", files[i]); cleanup (); exit (2); } xfclose (ofp); xfclose (fp); files[i] = tmp; } } ofp = xfopen (outfile, "w"); } else ofp = stdout; if (mergeonly) merge (files, nfiles, ofp); else sort (files, nfiles, ofp); cleanup (); /* If we wait for the implicit flush on exit, and the parent process has closed stdout (e.g., exec >&- in a shell), then the output file winds up empty. I don't understand why. This is under SunOS, Solaris, Ultrix, and Irix. This premature fflush makes the output reappear. --karl@cs.umb.edu */ if (fflush (ofp) < 0) error (1, errno, _("%s: write error"), outfile); if (have_read_stdin && fclose (stdin) == EOF) error (1, errno, outfile); if (ferror (stdout) || fclose (stdout) == EOF) error (1, errno, _("%s: write error"), outfile); exit (0); }