/* Support routines for GNU DIFF.
Copyright (C) 1988-1989, 1992-1995, 1998, 2001-2002, 2004, 2006, 2009-2013,
2015-2017 Free Software Foundation, Inc.
This file is part of GNU DIFF.
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 3 of the License, 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, see <http://www.gnu.org/licenses/>. */
#include "diff.h"
#include "argmatch.h"
#include "die.h"
#include <dirname.h>
#include <error.h>
#include <system-quote.h>
#include <xalloc.h>
#include "xvasprintf.h"
#include <signal.h>
/* Use SA_NOCLDSTOP as a proxy for whether the sigaction machinery is
present. */
#ifndef SA_NOCLDSTOP
# define SA_NOCLDSTOP 0
# define sigprocmask(How, Set, Oset) /* empty */
# define sigset_t int
# if ! HAVE_SIGINTERRUPT
# define siginterrupt(sig, flag) /* empty */
# endif
#endif
#ifndef SA_RESTART
# define SA_RESTART 0
#endif
char const pr_program[] = PR_PROGRAM;
/* Queue up one-line messages to be printed at the end,
when -l is specified. Each message is recorded with a 'struct msg'. */
struct msg
{
struct msg *next;
char args[1]; /* Format + 4 args, each '\0' terminated, concatenated. */
};
/* Head of the chain of queues messages. */
static struct msg *msg_chain;
/* Tail of the chain of queues messages. */
static struct msg **msg_chain_end = &msg_chain;
/* Use when a system call returns non-zero status.
NAME should normally be the file name. */
void
perror_with_name (char const *name)
{
error (0, errno, "%s", name);
}
/* Use when a system call returns non-zero status and that is fatal. */
void
pfatal_with_name (char const *name)
{
int e = errno;
print_message_queue ();
die (EXIT_TROUBLE, e, "%s", name);
}
/* Print an error message containing MSGID, then exit. */
void
fatal (char const *msgid)
{
print_message_queue ();
die (EXIT_TROUBLE, 0, "%s", _(msgid));
}
/* Like printf, except if -l in effect then save the message and print later.
This is used for things like "Only in ...". */
void
message (char const *format_msgid, char const *arg1, char const *arg2)
{
message5 (format_msgid, arg1, arg2, 0, 0);
}
void
message5 (char const *format_msgid, char const *arg1, char const *arg2,
char const *arg3, char const *arg4)
{
if (paginate)
{
char *p;
char const *arg[5];
int i;
size_t size[5];
size_t total_size = offsetof (struct msg, args);
struct msg *new;
arg[0] = format_msgid;
arg[1] = arg1;
arg[2] = arg2;
arg[3] = arg3 ? arg3 : "";
arg[4] = arg4 ? arg4 : "";
for (i = 0; i < 5; i++)
total_size += size[i] = strlen (arg[i]) + 1;
new = xmalloc (total_size);
for (i = 0, p = new->args; i < 5; p += size[i++])
memcpy (p, arg[i], size[i]);
*msg_chain_end = new;
new->next = 0;
msg_chain_end = &new->next;
}
else
{
if (sdiff_merge_assist)
putchar (' ');
printf (_(format_msgid), arg1, arg2, arg3, arg4);
}
}
/* Output all the messages that were saved up by calls to 'message'. */
void
print_message_queue (void)
{
char const *arg[5];
int i;
struct msg *m = msg_chain;
while (m)
{
struct msg *next = m->next;
arg[0] = m->args;
for (i = 0; i < 4; i++)
arg[i + 1] = arg[i] + strlen (arg[i]) + 1;
printf (_(arg[0]), arg[1], arg[2], arg[3], arg[4]);
free (m);
m = next;
}
}
/* The set of signals that are caught. */
static sigset_t caught_signals;
/* If nonzero, the value of the pending fatal signal. */
static sig_atomic_t volatile interrupt_signal;
/* A count of the number of pending stop signals that have been received. */
static sig_atomic_t volatile stop_signal_count;
/* An ordinary signal was received; arrange for the program to exit. */
static void
sighandler (int sig)
{
if (! SA_NOCLDSTOP)
signal (sig, SIG_IGN);
if (! interrupt_signal)
interrupt_signal = sig;
}
/* A SIGTSTP was received; arrange for the program to suspend itself. */
static void
stophandler (int sig)
{
if (! SA_NOCLDSTOP)
signal (sig, stophandler);
if (! interrupt_signal)
stop_signal_count++;
}
/* Process any pending signals. If signals are caught, this function
should be called periodically. Ideally there should never be an
unbounded amount of time when signals are not being processed.
Signal handling can restore the default colors, so callers must
immediately change colors after invoking this function. */
static void
process_signals (void)
{
while (interrupt_signal || stop_signal_count)
{
int sig;
int stops;
sigset_t oldset;
set_color_context (RESET_CONTEXT);
fflush (stdout);
sigprocmask (SIG_BLOCK, &caught_signals, &oldset);
/* Reload interrupt_signal and stop_signal_count, in case a new
signal was handled before sigprocmask took effect. */
sig = interrupt_signal;
stops = stop_signal_count;
/* SIGTSTP is special, since the application can receive that signal
more than once. In this case, don't set the signal handler to the
default. Instead, just raise the uncatchable SIGSTOP. */
if (stops)
{
stop_signal_count = stops - 1;
sig = SIGSTOP;
}
else
signal (sig, SIG_DFL);
/* Exit or suspend the program. */
raise (sig);
sigprocmask (SIG_SETMASK, &oldset, NULL);
/* If execution reaches here, then the program has been
continued (after being suspended). */
}
}
static void
install_signal_handlers (void)
{
/* The signals that are trapped, and the number of such signals. */
static int const sig[] =
{
/* This one is handled specially. */
SIGTSTP,
/* The usual suspects. */
SIGALRM, SIGHUP, SIGINT, SIGPIPE, SIGQUIT, SIGTERM,
#ifdef SIGPOLL
SIGPOLL,
#endif
#ifdef SIGPROF
SIGPROF,
#endif
#ifdef SIGVTALRM
SIGVTALRM,
#endif
#ifdef SIGXCPU
SIGXCPU,
#endif
#ifdef SIGXFSZ
SIGXFSZ,
#endif
};
enum { nsigs = sizeof (sig) / sizeof *(sig) };
#if ! SA_NOCLDSTOP
bool caught_sig[nsigs];
#endif
{
int j;
#if SA_NOCLDSTOP
struct sigaction act;
sigemptyset (&caught_signals);
for (j = 0; j < nsigs; j++)
{
sigaction (sig[j], NULL, &act);
if (act.sa_handler != SIG_IGN)
sigaddset (&caught_signals, sig[j]);
}
act.sa_mask = caught_signals;
act.sa_flags = SA_RESTART;
for (j = 0; j < nsigs; j++)
if (sigismember (&caught_signals, sig[j]))
{
act.sa_handler = sig[j] == SIGTSTP ? stophandler : sighandler;
sigaction (sig[j], &act, NULL);
}
#else
for (j = 0; j < nsigs; j++)
{
caught_sig[j] = (signal (sig[j], SIG_IGN) != SIG_IGN);
if (caught_sig[j])
{
signal (sig[j], sig[j] == SIGTSTP ? stophandler : sighandler);
siginterrupt (sig[j], 0);
}
}
#endif
}
}
static char const *current_name0;
static char const *current_name1;
static bool currently_recursive;
static bool colors_enabled;
static struct color_ext_type *color_ext_list = NULL;
struct bin_str
{
size_t len; /* Number of bytes */
const char *string; /* Pointer to the same */
};
struct color_ext_type
{
struct bin_str ext; /* The extension we're looking for */
struct bin_str seq; /* The sequence to output when we do */
struct color_ext_type *next; /* Next in list */
};
/* Parse a string as part of the --palette argument; this may involve
decoding all kinds of escape characters. If equals_end is set an
unescaped equal sign ends the string, otherwise only a : or \0
does. Set *OUTPUT_COUNT to the number of bytes output. Return
true if successful.
The resulting string is *not* null-terminated, but may contain
embedded nulls.
Note that both dest and src are char **; on return they point to
the first free byte after the array and the character that ended
the input string, respectively. */
static bool
get_funky_string (char **dest, const char **src, bool equals_end,
size_t *output_count)
{
char num; /* For numerical codes */
size_t count; /* Something to count with */
enum {
ST_GND, ST_BACKSLASH, ST_OCTAL, ST_HEX, ST_CARET, ST_END, ST_ERROR
} state;
const char *p;
char *q;
p = *src; /* We don't want to double-indirect */
q = *dest; /* the whole darn time. */
count = 0; /* No characters counted in yet. */
num = 0;
state = ST_GND; /* Start in ground state. */
while (state < ST_END)
{
switch (state)
{
case ST_GND: /* Ground state (no escapes) */
switch (*p)
{
case ':':
case '\0':
state = ST_END; /* End of string */
break;
case '\\':
state = ST_BACKSLASH; /* Backslash scape sequence */
++p;
break;
case '^':
state = ST_CARET; /* Caret escape */
++p;
break;
case '=':
if (equals_end)
{
state = ST_END; /* End */
break;
}
FALLTHROUGH;
default:
*(q++) = *(p++);
++count;
break;
}
break;
case ST_BACKSLASH: /* Backslash escaped character */
switch (*p)
{
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
state = ST_OCTAL; /* Octal sequence */
num = *p - '0';
break;
case 'x':
case 'X':
state = ST_HEX; /* Hex sequence */
num = 0;
break;
case 'a': /* Bell */
num = '\a';
break;
case 'b': /* Backspace */
num = '\b';
break;
case 'e': /* Escape */
num = 27;
break;
case 'f': /* Form feed */
num = '\f';
break;
case 'n': /* Newline */
num = '\n';
break;
case 'r': /* Carriage return */
num = '\r';
break;
case 't': /* Tab */
num = '\t';
break;
case 'v': /* Vtab */
num = '\v';
break;
case '?': /* Delete */
num = 127;
break;
case '_': /* Space */
num = ' ';
break;
case '\0': /* End of string */
state = ST_ERROR; /* Error! */
break;
default: /* Escaped character like \ ^ : = */
num = *p;
break;
}
if (state == ST_BACKSLASH)
{
*(q++) = num;
++count;
state = ST_GND;
}
++p;
break;
case ST_OCTAL: /* Octal sequence */
if (*p < '0' || *p > '7')
{
*(q++) = num;
++count;
state = ST_GND;
}
else
num = (num << 3) + (*(p++) - '0');
break;
case ST_HEX: /* Hex sequence */
switch (*p)
{
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
num = (num << 4) + (*(p++) - '0');
break;
case 'a':
case 'b':
case 'c':
case 'd':
case 'e':
case 'f':
num = (num << 4) + (*(p++) - 'a') + 10;
break;
case 'A':
case 'B':
case 'C':
case 'D':
case 'E':
case 'F':
num = (num << 4) + (*(p++) - 'A') + 10;
break;
default:
*(q++) = num;
++count;
state = ST_GND;
break;
}
break;
case ST_CARET: /* Caret escape */
state = ST_GND; /* Should be the next state... */
if (*p >= '@' && *p <= '~')
{
*(q++) = *(p++) & 037;
++count;
}
else if (*p == '?')
{
*(q++) = 127;
++count;
}
else
state = ST_ERROR;
break;
default:
abort ();
}
}
*dest = q;
*src = p;
*output_count = count;
return state != ST_ERROR;
}
enum parse_state
{
PS_START = 1,
PS_2,
PS_3,
PS_4,
PS_DONE,
PS_FAIL
};
#define LEN_STR_PAIR(s) sizeof (s) - 1, s
static struct bin_str color_indicator[] =
{
{ LEN_STR_PAIR ("\033[") }, /* lc: Left of color sequence */
{ LEN_STR_PAIR ("m") }, /* rc: Right of color sequence */
{ 0, NULL }, /* ec: End color (replaces lc+rs+rc) */
{ LEN_STR_PAIR ("0") }, /* rs: Reset to ordinary colors */
{ LEN_STR_PAIR ("1") }, /* hd: Header */
{ LEN_STR_PAIR ("32") }, /* ad: Add line */
{ LEN_STR_PAIR ("31") }, /* de: Delete line */
{ LEN_STR_PAIR ("36") }, /* ln: Line number */
};
static const char *const indicator_name[] =
{
"lc", "rc", "ec", "rs", "hd", "ad", "de", "ln", NULL
};
ARGMATCH_VERIFY (indicator_name, color_indicator);
static char const *color_palette;
void
set_color_palette (char const *palette)
{
color_palette = palette;
}
static void
parse_diff_color (void)
{
char *color_buf;
const char *p; /* Pointer to character being parsed */
char *buf; /* color_buf buffer pointer */
int ind_no; /* Indicator number */
char label[3]; /* Indicator label */
struct color_ext_type *ext; /* Extension we are working on */
if ((p = color_palette) == NULL || *p == '\0')
return;
ext = NULL;
strcpy (label, "??");
/* This is an overly conservative estimate, but any possible
--palette string will *not* generate a color_buf longer than
itself, so it is a safe way of allocating a buffer in
advance. */
buf = color_buf = xstrdup (p);
enum parse_state state = PS_START;
while (true)
{
switch (state)
{
case PS_START: /* First label character */
switch (*p)
{
case ':':
++p;
break;
case '*':
/* Allocate new extension block and add to head of
linked list (this way a later definition will
override an earlier one, which can be useful for
having terminal-specific defs override global). */
ext = xmalloc (sizeof *ext);
ext->next = color_ext_list;
color_ext_list = ext;
++p;
ext->ext.string = buf;
state = (get_funky_string (&buf, &p, true, &ext->ext.len)
? PS_4 : PS_FAIL);
break;
case '\0':
state = PS_DONE; /* Done! */
goto done;
default: /* Assume it is file type label */
label[0] = *(p++);
state = PS_2;
break;
}
break;
case PS_2: /* Second label character */
if (*p)
{
label[1] = *(p++);
state = PS_3;
}
else
state = PS_FAIL; /* Error */
break;
case PS_3: /* Equal sign after indicator label */
state = PS_FAIL; /* Assume failure... */
if (*(p++) == '=')/* It *should* be... */
{
for (ind_no = 0; indicator_name[ind_no] != NULL; ++ind_no)
{
if (STREQ (label, indicator_name[ind_no]))
{
color_indicator[ind_no].string = buf;
state = (get_funky_string (&buf, &p, false,
&color_indicator[ind_no].len)
? PS_START : PS_FAIL);
break;
}
}
if (state == PS_FAIL)
error (0, 0, _("unrecognized prefix: %s"), label);
}
break;
case PS_4: /* Equal sign after *.ext */
if (*(p++) == '=')
{
ext->seq.string = buf;
state = (get_funky_string (&buf, &p, false, &ext->seq.len)
? PS_START : PS_FAIL);
}
else
state = PS_FAIL;
break;
case PS_FAIL:
goto done;
default:
abort ();
}
}
done:
if (state == PS_FAIL)
{
struct color_ext_type *e;
struct color_ext_type *e2;
error (0, 0,
_("unparsable value for --palette"));
free (color_buf);
for (e = color_ext_list; e != NULL; /* empty */)
{
e2 = e;
e = e->next;
free (e2);
}
colors_enabled = false;
}
}
static void
check_color_output (bool is_pipe)
{
bool output_is_tty;
if (! outfile || colors_style == NEVER)
return;
output_is_tty = presume_output_tty || (!is_pipe && isatty (fileno (outfile)));
colors_enabled = (colors_style == ALWAYS
|| (colors_style == AUTO && output_is_tty));
if (colors_enabled)
parse_diff_color ();
if (output_is_tty)
install_signal_handlers ();
}
/* Call before outputting the results of comparing files NAME0 and NAME1
to set up OUTFILE, the stdio stream for the output to go to.
Usually, OUTFILE is just stdout. But when -l was specified
we fork off a 'pr' and make OUTFILE a pipe to it.
'pr' then outputs to our stdout. */
void
setup_output (char const *name0, char const *name1, bool recursive)
{
current_name0 = name0;
current_name1 = name1;
currently_recursive = recursive;
outfile = 0;
}
#if HAVE_WORKING_FORK
static pid_t pr_pid;
#endif
static char c_escape_char (char c)
{
switch (c) {
case '\a': return 'a';
case '\b': return 'b';
case '\t': return 't';
case '\n': return 'n';
case '\v': return 'v';
case '\f': return 'f';
case '\r': return 'r';
case '"': return '"';
case '\\': return '\\';
default:
return c < 32;
}
}
static char *
c_escape (char const *str)
{
char const *s;
size_t plus = 0;
bool must_quote = false;
for (s = str; *s; s++)
{
char c = *s;
if (c == ' ')
{
must_quote = true;
continue;
}
switch (c_escape_char (*s))
{
case 1:
plus += 3;
/* fall through */
case 0:
break;
default:
plus++;
break;
}
}
if (must_quote || plus)
{
size_t s_len = s - str;
char *buffer = xmalloc (s_len + plus + 3);
char *b = buffer;
*b++ = '"';
for (s = str; *s; s++)
{
char c = *s;
char escape = c_escape_char (c);
switch (escape)
{
case 0:
*b++ = c;
break;
case 1:
*b++ = '\\';
*b++ = ((c >> 6) & 03) + '0';
*b++ = ((c >> 3) & 07) + '0';
*b++ = ((c >> 0) & 07) + '0';
break;
default:
*b++ = '\\';
*b++ = escape;
break;
}
}
*b++ = '"';
*b = 0;
return buffer;
}
return (char *) str;
}
void
begin_output (void)
{
char *names[2];
char *name;
if (outfile != 0)
return;
names[0] = c_escape (current_name0);
names[1] = c_escape (current_name1);
/* Construct the header of this piece of diff. */
/* POSIX 1003.1-2001 specifies this format. But there are some bugs in
the standard: it says that we must print only the last component
of the pathnames, and it requires two spaces after "diff" if
there are no options. These requirements are silly and do not
match historical practice. */
name = xasprintf ("diff%s %s %s", switch_string, names[0], names[1]);
if (paginate)
{
char const *argv[4];
if (fflush (stdout) != 0)
pfatal_with_name (_("write failed"));
argv[0] = pr_program;
argv[1] = "-h";
argv[2] = name;
argv[3] = 0;
/* Make OUTFILE a pipe to a subsidiary 'pr'. */
{
#if HAVE_WORKING_FORK
int pipes[2];
if (pipe (pipes) != 0)
pfatal_with_name ("pipe");
pr_pid = fork ();
if (pr_pid < 0)
pfatal_with_name ("fork");
if (pr_pid == 0)
{
close (pipes[1]);
if (pipes[0] != STDIN_FILENO)
{
if (dup2 (pipes[0], STDIN_FILENO) < 0)
pfatal_with_name ("dup2");
close (pipes[0]);
}
execv (pr_program, (char **) argv);
_exit (errno == ENOENT ? 127 : 126);
}
else
{
close (pipes[0]);
outfile = fdopen (pipes[1], "w");
if (!outfile)
pfatal_with_name ("fdopen");
check_color_output (true);
}
#else
char *command = system_quote_argv (SCI_SYSTEM, (char **) argv);
errno = 0;
outfile = popen (command, "w");
if (!outfile)
pfatal_with_name (command);
check_color_output (true);
free (command);
#endif
}
}
else
{
/* If -l was not specified, output the diff straight to 'stdout'. */
outfile = stdout;
check_color_output (false);
/* If handling multiple files (because scanning a directory),
print which files the following output is about. */
if (currently_recursive)
printf ("%s\n", name);
}
free (name);
/* A special header is needed at the beginning of context output. */
switch (output_style)
{
case OUTPUT_CONTEXT:
print_context_header (files, (char const *const *)names, false);
break;
case OUTPUT_UNIFIED:
print_context_header (files, (char const *const *)names, true);
break;
default:
break;
}
if (names[0] != current_name0)
free (names[0]);
if (names[1] != current_name1)
free (names[1]);
}
/* Call after the end of output of diffs for one file.
Close OUTFILE and get rid of the 'pr' subfork. */
void
finish_output (void)
{
if (outfile != 0 && outfile != stdout)
{
int status;
int wstatus;
int werrno = 0;
if (ferror (outfile))
fatal ("write failed");
#if ! HAVE_WORKING_FORK
wstatus = pclose (outfile);
if (wstatus == -1)
werrno = errno;
#else
if (fclose (outfile) != 0)
pfatal_with_name (_("write failed"));
if (waitpid (pr_pid, &wstatus, 0) < 0)
pfatal_with_name ("waitpid");
#endif
status = (! werrno && WIFEXITED (wstatus)
? WEXITSTATUS (wstatus)
: INT_MAX);
if (status)
die (EXIT_TROUBLE, werrno,
_(status == 126
? "subsidiary program '%s' could not be invoked"
: status == 127
? "subsidiary program '%s' not found"
: status == INT_MAX
? "subsidiary program '%s' failed"
: "subsidiary program '%s' failed (exit status %d)"),
pr_program, status);
}
outfile = 0;
}
/* Compare two lines (typically one from each input file)
according to the command line options.
For efficiency, this is invoked only when the lines do not match exactly
but an option like -i might cause us to ignore the difference.
Return nonzero if the lines differ. */
bool
lines_differ_singlebyte (char const *s1, size_t s1len,
char const *s2, size_t s2len)
{
register char const *t1 = s1;
register char const *t2 = s2;
size_t column = 0;
while (1)
{
register unsigned char c1 = *t1++;
register unsigned char c2 = *t2++;
/* Test for exact char equality first, since it's a common case. */
if (c1 != c2)
{
switch (ignore_white_space)
{
case IGNORE_ALL_SPACE:
/* For -w, just skip past any white space. */
while (isspace (c1) && c1 != '\n') c1 = *t1++;
while (isspace (c2) && c2 != '\n') c2 = *t2++;
break;
case IGNORE_SPACE_CHANGE:
/* For -b, advance past any sequence of white space in
line 1 and consider it just one space, or nothing at
all if it is at the end of the line. */
if (isspace (c1))
{
while (c1 != '\n')
{
c1 = *t1++;
if (! isspace (c1))
{
--t1;
c1 = ' ';
break;
}
}
}
/* Likewise for line 2. */
if (isspace (c2))
{
while (c2 != '\n')
{
c2 = *t2++;
if (! isspace (c2))
{
--t2;
c2 = ' ';
break;
}
}
}
if (c1 != c2)
{
/* If we went too far when doing the simple test
for equality, go back to the first non-white-space
character in both sides and try again. */
if (c2 == ' ' && c1 != '\n'
&& s1 + 1 < t1
&& isspace ((unsigned char) t1[-2]))
{
--t1;
continue;
}
if (c1 == ' ' && c2 != '\n'
&& s2 + 1 < t2
&& isspace ((unsigned char) t2[-2]))
{
--t2;
continue;
}
}
break;
case IGNORE_TRAILING_SPACE:
case IGNORE_TAB_EXPANSION_AND_TRAILING_SPACE:
if (isspace (c1) && isspace (c2))
{
unsigned char c;
if (c1 != '\n')
{
char const *p = t1;
while ((c = *p) != '\n' && isspace (c))
++p;
if (c != '\n')
break;
}
if (c2 != '\n')
{
char const *p = t2;
while ((c = *p) != '\n' && isspace (c))
++p;
if (c != '\n')
break;
}
/* Both lines have nothing but whitespace left. */
return false;
}
if (ignore_white_space == IGNORE_TRAILING_SPACE)
break;
FALLTHROUGH;
case IGNORE_TAB_EXPANSION:
if ((c1 == ' ' && c2 == '\t')
|| (c1 == '\t' && c2 == ' '))
{
size_t column2 = column;
for (;; c1 = *t1++)
{
if (c1 == ' ')
column++;
else if (c1 == '\t')
column += tabsize - column % tabsize;
else
break;
}
for (;; c2 = *t2++)
{
if (c2 == ' ')
column2++;
else if (c2 == '\t')
column2 += tabsize - column2 % tabsize;
else
break;
}
if (column != column2)
return true;
}
break;
case IGNORE_NO_WHITE_SPACE:
break;
}
/* Lowercase all letters if -i is specified. */
if (ignore_case)
{
c1 = tolower (c1);
c2 = tolower (c2);
}
if (c1 != c2)
break;
}
if (c1 == '\n')
return false;
column += c1 == '\t' ? tabsize - column % tabsize : 1;
}
return true;
}
#ifdef HANDLE_MULTIBYTE
# define MBC2WC(T, END, MBLENGTH, WC, STATE, CONVFAIL) \
do \
{ \
mbstate_t bak = STATE; \
\
CONVFAIL = 0; \
MBLENGTH = mbrtowc (&WC, T, END - T, &STATE); \
\
switch (MBLENGTH) \
{ \
case (size_t)-2: \
case (size_t)-1: \
STATE = bak; \
++CONVFAIL; \
/* Fall through. */ \
case 0: \
MBLENGTH = 1; \
} \
} \
while (0)
bool
lines_differ_multibyte (char const *s1, size_t s1len,
char const *s2, size_t s2len)
{
char const *end1, *end2;
char c1, c2;
wchar_t wc1, wc2, wc1_bak, wc2_bak;
size_t mblen1, mblen2;
mbstate_t state1, state2, state1_bak, state2_bak;
int convfail1, convfail2, convfail1_bak, convfail2_bak;
char const *t1 = s1;
char const *t2 = s2;
char const *t1_bak, *t2_bak;
size_t column = 0;
if (ignore_white_space == IGNORE_NO_WHITE_SPACE && !ignore_case)
{
while (*t1 != '\n')
if (*t1++ != *t2++)
return 1;
return 0;
}
end1 = t1 + s1len;
end2 = t2 + s2len;
memset (&state1, '\0', sizeof (mbstate_t));
memset (&state2, '\0', sizeof (mbstate_t));
while (1)
{
c1 = *t1;
c2 = *t2;
MBC2WC (t1, end1, mblen1, wc1, state1, convfail1);
MBC2WC (t2, end2, mblen2, wc2, state2, convfail2);
/* Test for exact char equality first, since it's a common case. */
if (convfail1 ^ convfail2)
break;
else if (convfail1 && convfail2 && c1 != c2)
break;
else if (!convfail1 && !convfail2 && wc1 != wc2)
{
switch (ignore_white_space)
{
case IGNORE_ALL_SPACE:
/* For -w, just skip past any white space. */
while (1)
{
if (convfail1)
break;
else if (wc1 == L'\n' || !iswspace (wc1))
break;
t1 += mblen1;
c1 = *t1;
MBC2WC (t1, end1, mblen1, wc1, state1, convfail1);
}
while (1)
{
if (convfail2)
break;
else if (wc2 == L'\n' || !iswspace (wc2))
break;
t2 += mblen2;
c2 = *t2;
MBC2WC (t2, end2, mblen2, wc2, state2, convfail2);
}
t1 += mblen1;
t2 += mblen2;
break;
case IGNORE_SPACE_CHANGE:
/* For -b, advance past any sequence of white space in
line 1 and consider it just one space, or nothing at
all if it is at the end of the line. */
if (wc1 != L'\n' && iswspace (wc1))
{
size_t mblen_bak;
mbstate_t state_bak;
do
{
t1 += mblen1;
mblen_bak = mblen1;
state_bak = state1;
MBC2WC (t1, end1, mblen1, wc1, state1, convfail1);
}
while (!convfail1 && (wc1 != L'\n' && iswspace (wc1)));
state1 = state_bak;
mblen1 = mblen_bak;
t1 -= mblen1;
convfail1 = 0;
wc1 = L' ';
}
/* Likewise for line 2. */
if (wc2 != L'\n' && iswspace (wc2))
{
size_t mblen_bak;
mbstate_t state_bak;
do
{
t2 += mblen2;
mblen_bak = mblen2;
state_bak = state2;
MBC2WC (t2, end2, mblen2, wc2, state2, convfail2);
}
while (!convfail2 && (wc2 != L'\n' && iswspace (wc2)));
state2 = state_bak;
mblen2 = mblen_bak;
t2 -= mblen2;
convfail2 = 0;
wc2 = L' ';
}
if (wc1 != wc2)
{
/* If we went too far when doing the simple test for
equality, go back to the first non-whitespace
character in both sides and try again. */
if (wc2 == L' ' && wc1 != L'\n' &&
t1 > s1 &&
!convfail1_bak && iswspace (wc1_bak))
{
t1 = t1_bak;
wc1 = wc1_bak;
state1 = state1_bak;
convfail1 = convfail1_bak;
continue;
}
if (wc1 == L' ' && wc2 != L'\n'
&& t2 > s2
&& !convfail2_bak && iswspace (wc2_bak))
{
t2 = t2_bak;
wc2 = wc2_bak;
state2 = state2_bak;
convfail2 = convfail2_bak;
continue;
}
}
t1_bak = t1; t2_bak = t2;
wc1_bak = wc1; wc2_bak = wc2;
state1_bak = state1; state2_bak = state2;
convfail1_bak = convfail1; convfail2_bak = convfail2;
if (wc1 == L'\n')
wc1 = L' ';
else
t1 += mblen1;
if (wc2 == L'\n')
wc2 = L' ';
else
t2 += mblen2;
break;
case IGNORE_TRAILING_SPACE:
case IGNORE_TAB_EXPANSION_AND_TRAILING_SPACE:
if (iswspace (wc1) && iswspace (wc2))
{
char const *p;
wchar_t wc;
size_t mblength;
int convfail;
mbstate_t state;
bool just_whitespace_left = 1;
if (wc1 != L'\n')
{
mblength = mblen1;
p = t1;
memset (&state, '\0', sizeof(mbstate_t));
while (p < end1)
{
if (*p == '\n')
break;
p += mblength;
MBC2WC (p, end1, mblength, wc, state, convfail);
if (convfail || !iswspace (wc))
{
just_whitespace_left = 0;
break;
}
}
}
if (just_whitespace_left && wc2 != L'\n')
{
mblength = mblen2;
p = t2;
memset (&state, '\0', sizeof(mbstate_t));
while (p < end2)
{
if (*p == '\n')
break;
p += mblength;
MBC2WC (p, end2, mblength, wc, state, convfail);
if (convfail || !iswspace (wc))
{
just_whitespace_left = 0;
break;
}
}
}
if (just_whitespace_left)
/* Both lines have nothing but whitespace left. */
return false;
}
if (ignore_white_space == IGNORE_TRAILING_SPACE)
break;
/* Fall through. */
case IGNORE_TAB_EXPANSION:
if ((wc1 == L' ' && wc2 == L'\t')
|| (wc1 == L'\t' && wc2 == L' '))
{
size_t column2 = column;
while (1)
{
if (convfail1)
{
++t1;
break;
}
else if (wc1 == L' ')
column++;
else if (wc1 == L'\t')
column += tabsize - column % tabsize;
else
{
t1 += mblen1;
break;
}
t1 += mblen1;
c1 = *t1;
MBC2WC (t1, end1, mblen1, wc1, state1, convfail1);
}
while (1)
{
if (convfail2)
{
++t2;
break;
}
else if (wc2 == L' ')
column2++;
else if (wc2 == L'\t')
column2 += tabsize - column2 % tabsize;
else
{
t2 += mblen2;
break;
}
t2 += mblen2;
c2 = *t2;
MBC2WC (t2, end2, mblen2, wc2, state2, convfail2);
}
if (column != column2)
return 1;
}
else
{
t1 += mblen1;
t2 += mblen2;
}
break;
case IGNORE_NO_WHITE_SPACE:
t1 += mblen1;
t2 += mblen2;
break;
}
/* Lowercase all letters if -i is specified. */
if (ignore_case)
{
if (!convfail1)
wc1 = towlower (wc1);
if (!convfail2)
wc2 = towlower (wc2);
}
if (convfail1 ^ convfail2)
break;
else if (convfail1 && convfail2 && c1 != c2)
break;
else if (!convfail1 && !convfail2 && wc1 != wc2)
break;
}
else
{
t1_bak = t1; t2_bak = t2;
wc1_bak = wc1; wc2_bak = wc2;
state1_bak = state1; state2_bak = state2;
convfail1_bak = convfail1; convfail2_bak = convfail2;
t1 += mblen1; t2 += mblen2;
}
if (!convfail1 && wc1 == L'\n')
return 0;
column += convfail1 ? 1 :
(wc1 == L'\t') ? tabsize - column % tabsize : wcwidth (wc1);
}
return 1;
}
#endif
/* Find the consecutive changes at the start of the script START.
Return the last link before the first gap. */
struct change * _GL_ATTRIBUTE_CONST
find_change (struct change *start)
{
return start;
}
struct change * _GL_ATTRIBUTE_CONST
find_reverse_change (struct change *start)
{
return start;
}
/* Divide SCRIPT into pieces by calling HUNKFUN and
print each piece with PRINTFUN.
Both functions take one arg, an edit script.
HUNKFUN is called with the tail of the script
and returns the last link that belongs together with the start
of the tail.
PRINTFUN takes a subscript which belongs together (with a null
link at the end) and prints it. */
void
print_script (struct change *script,
struct change * (*hunkfun) (struct change *),
void (*printfun) (struct change *))
{
struct change *next = script;
while (next)
{
struct change *this, *end;
/* Find a set of changes that belong together. */
this = next;
end = (*hunkfun) (next);
/* Disconnect them from the rest of the changes,
making them a hunk, and remember the rest for next iteration. */
next = end->link;
end->link = 0;
#ifdef DEBUG
debug_script (this);
#endif
/* Print this hunk. */
(*printfun) (this);
/* Reconnect the script so it will all be freed properly. */
end->link = next;
}
}
/* Print the text of a single line LINE,
flagging it with the characters in LINE_FLAG (which say whether
the line is inserted, deleted, changed, etc.). LINE_FLAG must not
end in a blank, unless it is a single blank. */
void
print_1_line (char const *line_flag, char const *const *line)
{
print_1_line_nl (line_flag, line, false);
}
/* Print the text of a single line LINE,
flagging it with the characters in LINE_FLAG (which say whether
the line is inserted, deleted, changed, etc.). LINE_FLAG must not
end in a blank, unless it is a single blank. If SKIP_NL is set, then
the final '\n' is not printed. */
void
print_1_line_nl (char const *line_flag, char const *const *line, bool skip_nl)
{
char const *base = line[0], *limit = line[1]; /* Help the compiler. */
FILE *out = outfile; /* Help the compiler some more. */
char const *flag_format = 0;
/* If -T was specified, use a Tab between the line-flag and the text.
Otherwise use a Space (as Unix diff does).
Print neither space nor tab if line-flags are empty.
But omit trailing blanks if requested. */
if (line_flag && *line_flag)
{
char const *flag_format_1 = flag_format = initial_tab ? "%s\t" : "%s ";
char const *line_flag_1 = line_flag;
if (suppress_blank_empty && **line == '\n')
{
flag_format_1 = "%s";
/* This hack to omit trailing blanks takes advantage of the
fact that the only way that LINE_FLAG can end in a blank
is when LINE_FLAG consists of a single blank. */
line_flag_1 += *line_flag_1 == ' ';
}
fprintf (out, flag_format_1, line_flag_1);
}
output_1_line (base, limit - (skip_nl && limit[-1] == '\n'), flag_format, line_flag);
if ((!line_flag || line_flag[0]) && limit[-1] != '\n')
{
set_color_context (RESET_CONTEXT);
fprintf (out, "\n\\ %s\n", _("No newline at end of file"));
}
}
/* Output a line from BASE up to LIMIT.
With -t, expand white space characters to spaces, and if FLAG_FORMAT
is nonzero, output it with argument LINE_FLAG after every
internal carriage return, so that tab stops continue to line up. */
void
output_1_line (char const *base, char const *limit, char const *flag_format,
char const *line_flag)
{
const size_t MAX_CHUNK = 1024;
if (!expand_tabs)
{
size_t left = limit - base;
while (left)
{
size_t to_write = MIN (left, MAX_CHUNK);
size_t written = fwrite (base, sizeof (char), to_write, outfile);
if (written < to_write)
return;
base += written;
left -= written;
process_signals ();
}
}
else
{
register FILE *out = outfile;
register unsigned char c;
register char const *t = base;
register size_t column = 0;
size_t tab_size = tabsize;
size_t counter_proc_signals = 0;
while (t < limit)
{
counter_proc_signals++;
if (counter_proc_signals == MAX_CHUNK)
{
process_signals ();
counter_proc_signals = 0;
}
switch ((c = *t++))
{
case '\t':
{
size_t spaces = tab_size - column % tab_size;
column += spaces;
do
putc (' ', out);
while (--spaces);
}
break;
case '\r':
putc (c, out);
if (flag_format && t < limit && *t != '\n')
fprintf (out, flag_format, line_flag);
column = 0;
break;
case '\b':
if (column == 0)
continue;
column--;
putc (c, out);
break;
default:
column += isprint (c) != 0;
putc (c, out);
break;
}
}
}
}
enum indicator_no
{
C_LEFT, C_RIGHT, C_END, C_RESET, C_HEADER, C_ADD, C_DELETE, C_LINE
};
static void
put_indicator (const struct bin_str *ind)
{
fwrite (ind->string, ind->len, 1, outfile);
}
static enum color_context last_context = RESET_CONTEXT;
void
set_color_context (enum color_context color_context)
{
if (color_context != RESET_CONTEXT)
process_signals ();
if (colors_enabled && last_context != color_context)
{
put_indicator (&color_indicator[C_LEFT]);
switch (color_context)
{
case HEADER_CONTEXT:
put_indicator (&color_indicator[C_HEADER]);
break;
case LINE_NUMBER_CONTEXT:
put_indicator (&color_indicator[C_LINE]);
break;
case ADD_CONTEXT:
put_indicator (&color_indicator[C_ADD]);
break;
case DELETE_CONTEXT:
put_indicator (&color_indicator[C_DELETE]);
break;
case RESET_CONTEXT:
put_indicator (&color_indicator[C_RESET]);
break;
default:
abort ();
}
put_indicator (&color_indicator[C_RIGHT]);
last_context = color_context;
}
}
char const change_letter[] = { 0, 'd', 'a', 'c' };
/* Translate an internal line number (an index into diff's table of lines)
into an actual line number in the input file.
The internal line number is I. FILE points to the data on the file.
Internal line numbers count from 0 starting after the prefix.
Actual line numbers count from 1 within the entire file. */
lin _GL_ATTRIBUTE_PURE
translate_line_number (struct file_data const *file, lin i)
{
return i + file->prefix_lines + 1;
}
/* Translate a line number range. This is always done for printing,
so for convenience translate to printint rather than lin, so that the
caller can use printf with "%"pI"d" without casting. */
void
translate_range (struct file_data const *file,
lin a, lin b,
printint *aptr, printint *bptr)
{
*aptr = translate_line_number (file, a - 1) + 1;
*bptr = translate_line_number (file, b + 1) - 1;
}
/* Print a pair of line numbers with SEPCHAR, translated for file FILE.
If the two numbers are identical, print just one number.
Args A and B are internal line numbers.
We print the translated (real) line numbers. */
void
print_number_range (char sepchar, struct file_data *file, lin a, lin b)
{
printint trans_a, trans_b;
translate_range (file, a, b, &trans_a, &trans_b);
/* Note: we can have B < A in the case of a range of no lines.
In this case, we should print the line number before the range,
which is B. */
if (trans_b > trans_a)
fprintf (outfile, "%"pI"d%c%"pI"d", trans_a, sepchar, trans_b);
else
fprintf (outfile, "%"pI"d", trans_b);
}
/* Look at a hunk of edit script and report the range of lines in each file
that it applies to. HUNK is the start of the hunk, which is a chain
of 'struct change'. The first and last line numbers of file 0 are stored in
*FIRST0 and *LAST0, and likewise for file 1 in *FIRST1 and *LAST1.
Note that these are internal line numbers that count from 0.
If no lines from file 0 are deleted, then FIRST0 is LAST0+1.
Return UNCHANGED if only ignorable lines are inserted or deleted,
OLD if lines of file 0 are deleted,
NEW if lines of file 1 are inserted,
and CHANGED if both kinds of changes are found. */
enum changes
analyze_hunk (struct change *hunk,
lin *first0, lin *last0,
lin *first1, lin *last1)
{
struct change *next;
lin l0, l1;
lin show_from, show_to;
lin i;
bool trivial = ignore_blank_lines || ignore_regexp.fastmap;
size_t trivial_length = ignore_blank_lines - 1;
/* If 0, ignore zero-length lines;
if SIZE_MAX, do not ignore lines just because of their length. */
bool skip_white_space =
ignore_blank_lines && IGNORE_TRAILING_SPACE <= ignore_white_space;
bool skip_leading_white_space =
skip_white_space && IGNORE_SPACE_CHANGE <= ignore_white_space;
char const * const *linbuf0 = files[0].linbuf; /* Help the compiler. */
char const * const *linbuf1 = files[1].linbuf;
show_from = show_to = 0;
*first0 = hunk->line0;
*first1 = hunk->line1;
next = hunk;
do
{
l0 = next->line0 + next->deleted - 1;
l1 = next->line1 + next->inserted - 1;
show_from += next->deleted;
show_to += next->inserted;
for (i = next->line0; i <= l0 && trivial; i++)
{
char const *line = linbuf0[i];
char const *lastbyte = linbuf0[i + 1] - 1;
char const *newline = lastbyte + (*lastbyte != '\n');
size_t len = newline - line;
char const *p = line;
if (skip_white_space)
for (; *p != '\n'; p++)
if (! isspace ((unsigned char) *p))
{
if (! skip_leading_white_space)
p = line;
break;
}
if (newline - p != trivial_length
&& (! ignore_regexp.fastmap
|| re_search (&ignore_regexp, line, len, 0, len, 0) < 0))
trivial = 0;
}
for (i = next->line1; i <= l1 && trivial; i++)
{
char const *line = linbuf1[i];
char const *lastbyte = linbuf1[i + 1] - 1;
char const *newline = lastbyte + (*lastbyte != '\n');
size_t len = newline - line;
char const *p = line;
if (skip_white_space)
for (; *p != '\n'; p++)
if (! isspace ((unsigned char) *p))
{
if (! skip_leading_white_space)
p = line;
break;
}
if (newline - p != trivial_length
&& (! ignore_regexp.fastmap
|| re_search (&ignore_regexp, line, len, 0, len, 0) < 0))
trivial = 0;
}
}
while ((next = next->link) != 0);
*last0 = l0;
*last1 = l1;
/* If all inserted or deleted lines are ignorable,
tell the caller to ignore this hunk. */
if (trivial)
return UNCHANGED;
return (show_from ? OLD : UNCHANGED) | (show_to ? NEW : UNCHANGED);
}
/* Concatenate three strings, returning a newly malloc'd string. */
char *
concat (char const *s1, char const *s2, char const *s3)
{
char *new = xmalloc (strlen (s1) + strlen (s2) + strlen (s3) + 1);
sprintf (new, "%s%s%s", s1, s2, s3);
return new;
}
/* Yield a new block of SIZE bytes, initialized to zero. */
void *
zalloc (size_t size)
{
void *p = xmalloc (size);
memset (p, 0, size);
return p;
}
void
debug_script (struct change *sp)
{
fflush (stdout);
for (; sp; sp = sp->link)
{
printint line0 = sp->line0;
printint line1 = sp->line1;
printint deleted = sp->deleted;
printint inserted = sp->inserted;
fprintf (stderr, "%3"pI"d %3"pI"d delete %"pI"d insert %"pI"d\n",
line0, line1, deleted, inserted);
}
fflush (stderr);
}