sbase/find.c

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/* See LICENSE file for copyright and license details. */
#include <dirent.h>
#include <fnmatch.h>
#include <grp.h>
#include <libgen.h>
#include <pwd.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <sys/stat.h>
#include <sys/wait.h>
#include "util.h"
/* because putting integers in pointers is undefined by the standard */
union extra {
void *p;
intptr_t i;
};
/* Argument passed into a primary's function */
struct arg {
char *path;
struct stat *st;
union extra extra;
};
/* Information about each primary, for lookup table */
struct pri_info {
char *name;
int (*func)(struct arg *arg);
char **(*getarg)(char **argv, union extra *extra);
void (*freearg)(union extra extra);
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char narg; /* -xdev, -depth, -print don't take args but have getarg() */
};
/* Information about operators, for lookup table */
struct op_info {
char *name; /* string representation of op */
char type; /* from tok.type */
char prec; /* precedence */
char nargs; /* number of arguments (unary or binary) */
char lassoc; /* left associative */
};
/* Token when lexing/parsing
* (although also used for the expression tree) */
struct tok {
struct tok *left, *right; /* if (type == NOT) left = NULL */
union extra extra;
union {
struct pri_info *pinfo; /* if (type == PRIM) */
struct op_info *oinfo;
} u;
enum {
PRIM = 0, LPAR, RPAR, NOT, AND, OR, END
} type;
};
/* structures used for arg.extra.p and tok.extra.p */
struct permarg {
mode_t mode;
char exact;
};
struct okarg {
char ***braces;
char **argv;
};
/* for all arguments that take a number
* +n, n, -n mean > n, == n, < n respectively */
struct narg {
int (*cmp)(int a, int b);
int n;
};
struct sizearg {
struct narg n;
char bytes; /* size is in bytes, not 512 byte sectors */
};
struct execarg {
union {
struct {
char ***braces; /* NULL terminated list of pointers into argv where {} were */
} s; /* semicolon */
struct {
size_t arglen; /* number of bytes in argv before files are added */
size_t filelen; /* numer of bytes in file names added to argv */
size_t first; /* index one past last arg, where first file goes */
size_t next; /* index where next file goes */
size_t cap; /* capacity of argv */
} p; /* plus */
} u;
char **argv; /* NULL terminated list of arguments (allocated if isplus) */
char isplus; /* -exec + instead of -exec ; */
};
/* used to find loops while recursing through directory structure */
struct findhist {
struct findhist *next;
char *path;
dev_t dev;
ino_t ino;
};
/* Primaries */
static int pri_name (struct arg *arg);
static int pri_path (struct arg *arg);
static int pri_nouser (struct arg *arg);
static int pri_nogroup(struct arg *arg);
static int pri_xdev (struct arg *arg);
static int pri_prune (struct arg *arg);
static int pri_perm (struct arg *arg);
static int pri_type (struct arg *arg);
static int pri_links (struct arg *arg);
static int pri_user (struct arg *arg);
static int pri_group (struct arg *arg);
static int pri_size (struct arg *arg);
static int pri_atime (struct arg *arg);
static int pri_ctime (struct arg *arg);
static int pri_mtime (struct arg *arg);
static int pri_exec (struct arg *arg);
static int pri_ok (struct arg *arg);
static int pri_print (struct arg *arg);
static int pri_newer (struct arg *arg);
static int pri_depth (struct arg *arg);
/* Getargs */
static char **get_name_arg (char *argv[], union extra *extra);
static char **get_path_arg (char *argv[], union extra *extra);
static char **get_xdev_arg (char *argv[], union extra *extra);
static char **get_perm_arg (char *argv[], union extra *extra);
static char **get_type_arg (char *argv[], union extra *extra);
static char **get_n_arg (char *argv[], union extra *extra);
static char **get_user_arg (char *argv[], union extra *extra);
static char **get_group_arg(char *argv[], union extra *extra);
static char **get_size_arg (char *argv[], union extra *extra);
static char **get_exec_arg (char *argv[], union extra *extra);
static char **get_ok_arg (char *argv[], union extra *extra);
static char **get_print_arg(char *argv[], union extra *extra);
static char **get_newer_arg(char *argv[], union extra *extra);
static char **get_depth_arg(char *argv[], union extra *extra);
/* Freeargs */
static void free_extra (union extra extra);
static void free_exec_arg(union extra extra);
static void free_ok_arg (union extra extra);
/* Parsing/Building/Running */
static void fill_narg(char *s, struct narg *n);
static struct pri_info *find_primary(char *name);
static struct op_info *find_op(char *name);
static void parse(int argc, char **argv);
static int eval(struct tok *tok, struct arg *arg);
static void find(char *path, struct findhist *hist);
static void usage(void);
/* for comparisons with narg */
static int cmp_gt(int a, int b) { return a > b; }
static int cmp_eq(int a, int b) { return a == b; }
static int cmp_lt(int a, int b) { return a < b; }
/* order from find(1p), may want to alphabetize */
static struct pri_info primaries[] = {
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{ "-name" , pri_name , get_name_arg , NULL , 1 },
{ "-path" , pri_path , get_path_arg , NULL , 1 },
{ "-nouser" , pri_nouser , NULL , NULL , 1 },
{ "-nogroup", pri_nogroup, NULL , NULL , 1 },
{ "-xdev" , pri_xdev , get_xdev_arg , NULL , 0 },
{ "-prune" , pri_prune , NULL , NULL , 1 },
{ "-perm" , pri_perm , get_perm_arg , free_extra , 1 },
{ "-type" , pri_type , get_type_arg , NULL , 1 },
{ "-links" , pri_links , get_n_arg , free_extra , 1 },
{ "-user" , pri_user , get_user_arg , NULL , 1 },
{ "-group" , pri_group , get_group_arg, NULL , 1 },
{ "-size" , pri_size , get_size_arg , free_extra , 1 },
{ "-atime" , pri_atime , get_n_arg , free_extra , 1 },
{ "-ctime" , pri_ctime , get_n_arg , free_extra , 1 },
{ "-mtime" , pri_mtime , get_n_arg , free_extra , 1 },
{ "-exec" , pri_exec , get_exec_arg , free_exec_arg, 1 },
{ "-ok" , pri_ok , get_ok_arg , free_ok_arg , 1 },
{ "-print" , pri_print , get_print_arg, NULL , 0 },
{ "-newer" , pri_newer , get_newer_arg, NULL , 1 },
{ "-depth" , pri_depth , get_depth_arg, NULL , 0 },
{ NULL, NULL, NULL, NULL, 0 }
};
static struct op_info ops[] = {
{ "(" , LPAR, 0, 0, 0 }, /* parens are handled specially */
{ ")" , RPAR, 0, 0, 0 },
{ "!" , NOT , 3, 1, 0 },
{ "-a", AND , 2, 2, 1 },
{ "-o", OR , 1, 2, 1 },
{ NULL, 0, 0, 0, 0 }
};
extern char **environ;
static struct tok *toks; /* holds allocated array of all toks created while parsing */
static struct tok *root; /* points to root of expression tree, inside toks array */
static struct timespec start; /* time find was started, used for -[acm]time */
static size_t envlen; /* number of bytes in environ, used to calculate against ARG_MAX */
static size_t argmax; /* value of ARG_MAX retrieved using sysconf(3p) */
static struct {
char ret ; /* return value from main */
char depth; /* -depth, directory contents before directory itself */
char h ; /* -H, follow symlinks on command line */
char l ; /* -L, follow all symlinks (command line and search) */
char prune; /* hit -prune */
char xdev ; /* -xdev, prune directories on different devices */
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char print; /* whether we will need -print when parsing */
} gflags;
/*
* Primaries
*/
static int
pri_name(struct arg *arg)
{
return !fnmatch((char *)arg->extra.p, basename(arg->path), 0);
}
static int
pri_path(struct arg *arg)
{
return !fnmatch((char *)arg->extra.p, arg->path, 0);
}
/* FIXME: what about errors? find(1p) literally just says
* "for which the getpwuid() function ... returns NULL" */
static int
pri_nouser(struct arg *arg)
{
return !getpwuid(arg->st->st_uid);
}
static int
pri_nogroup(struct arg *arg)
{
return !getgrgid(arg->st->st_gid);
}
static int
pri_xdev(struct arg *arg)
{
return 1;
}
static int
pri_prune(struct arg *arg)
{
return gflags.prune = 1;
}
static int
pri_perm(struct arg *arg)
{
struct permarg *p = (struct permarg *)arg->extra.p;
return (arg->st->st_mode & 07777 & (p->exact ? -1U : p->mode)) == p->mode;
}
static int
pri_type(struct arg *arg)
{
switch ((char)arg->extra.i) {
default : return 0; /* impossible, but placate warnings */
case 'b': return S_ISBLK (arg->st->st_mode);
case 'c': return S_ISCHR (arg->st->st_mode);
case 'd': return S_ISDIR (arg->st->st_mode);
case 'l': return S_ISLNK (arg->st->st_mode);
case 'p': return S_ISFIFO(arg->st->st_mode);
case 'f': return S_ISREG (arg->st->st_mode);
case 's': return S_ISSOCK(arg->st->st_mode);
}
}
static int
pri_links(struct arg *arg)
{
struct narg *n = arg->extra.p;
return n->cmp(arg->st->st_nlink, n->n);
}
static int
pri_user(struct arg *arg)
{
return arg->st->st_uid == (uid_t)arg->extra.i;
}
static int
pri_group(struct arg *arg)
{
return arg->st->st_gid == (gid_t)arg->extra.i;
}
static int
pri_size(struct arg *arg)
{
struct sizearg *s = arg->extra.p;
off_t size = arg->st->st_size;
if (!s->bytes)
size = size / 512 + !!(size % 512);
return s->n.cmp(size, s->n.n);
}
/* FIXME: ignoring nanoseconds in atime, ctime, mtime */
static int
pri_atime(struct arg *arg)
{
struct narg *n = arg->extra.p;
time_t time = (n->n - start.tv_sec) / 86400;
return n->cmp(time, n->n);
}
static int
pri_ctime(struct arg *arg)
{
struct narg *n = arg->extra.p;
time_t time = (n->n - start.tv_sec) / 86400;
return n->cmp(time, n->n);
}
static int
pri_mtime(struct arg *arg)
{
struct narg *n = arg->extra.p;
time_t time = (n->n - start.tv_sec) / 86400;
return n->cmp(time, n->n);
}
static int
pri_exec(struct arg *arg)
{
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int status;
size_t len;
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pid_t pid;
char **sp, ***brace;
struct execarg *e = arg->extra.p;
if (e->isplus) {
len = strlen(arg->path) + 1;
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/* if we reached ARG_MAX, fork, exec, wait, free file names, reset list */
if (len + e->u.p.arglen + e->u.p.filelen + envlen > argmax) {
e->argv[e->u.p.next] = NULL;
switch((pid = fork())) {
case -1:
eprintf("fork:");
case 0:
execvp(*e->argv, e->argv);
weprintf("exec %s failed:", *e->argv);
_exit(1);
}
waitpid(pid, &status, 0);
gflags.ret = gflags.ret || status;
for (sp = e->argv + e->u.p.first; *sp; sp++)
free(*sp);
e->u.p.next = e->u.p.first;
e->u.p.filelen = 0;
}
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/* if we have too many files, realloc (with space for NULL termination) */
if (e->u.p.next + 1 == e->u.p.cap)
e->argv = ereallocarray(e->argv, e->u.p.cap *= 2, sizeof(*e->argv));
e->argv[e->u.p.next++] = estrdup(arg->path);
e->u.p.filelen += len + sizeof(arg->path);
return 1;
} else {
/* insert path everywhere user gave us {} */
for (brace = e->u.s.braces; *brace; brace++)
**brace = arg->path;
switch((pid = fork())) {
case -1:
eprintf("fork:");
case 0:
execvp(*e->argv, e->argv);
weprintf("exec %s failed:", *e->argv);
_exit(1);
}
/* FIXME: propper course of action for all waitpid() on EINTR? */
waitpid(pid, &status, 0);
return !!status;
}
}
static int
pri_ok(struct arg *arg)
{
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int status, reply;
pid_t pid;
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char ***brace, buf[256];
struct okarg *o = arg->extra.p;
fprintf(stderr, "%s: %s ?", *o->argv, arg->path);
reply = fgetc(stdin);
/* throw away rest of line */
while (fgets(buf, sizeof(buf), stdin) && *buf && buf[strlen(buf) - 1] == '\n')
/* FIXME: what if the first character of the rest of the line is a null
* byte? probably shouldn't juse fgets() */
;
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if (feof(stdin)) /* FIXME: ferror()? */
clearerr(stdin);
if (reply != 'y' && reply != 'Y')
return 0;
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/* insert filename everywhere user gave us {} */
for (brace = o->braces; *brace; brace++)
**brace = arg->path;
switch((pid = fork())) {
case -1:
eprintf("fork:");
case 0:
execvp(*o->argv, o->argv);
weprintf("exec %s failed:", *o->argv);
_exit(1);
}
waitpid(pid, &status, 0);
return !!status;
}
static int
pri_print(struct arg *arg)
{
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if (puts(arg->path) == EOF)
eprintf("puts failed:");
return 1;
}
/* FIXME: ignoring nanoseconds */
static int
pri_newer(struct arg *arg)
{
return arg->st->st_mtime > (time_t)arg->extra.i;
}
static int
pri_depth(struct arg *arg)
{
return 1;
}
/*
* Getargs
* consume any arguments for given primary and fill extra
* return pointer to last argument, the pointer will be incremented in parse()
*/
static char **
get_name_arg(char *argv[], union extra *extra)
{
extra->p = *argv;
return argv;
}
static char **
get_path_arg(char *argv[], union extra *extra)
{
extra->p = *argv;
return argv;
}
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static char **
get_xdev_arg(char *argv[], union extra *extra)
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{
gflags.xdev = 1;
return argv;
}
static char **
get_perm_arg(char *argv[], union extra *extra)
{
struct permarg *p = extra->p = emalloc(sizeof(*p));
if (**argv == '-')
(*argv)++;
else
p->exact = 1;
p->mode = parsemode(*argv, 0, 0);
return argv;
}
static char **
get_type_arg(char *argv[], union extra *extra)
{
if (!strchr("bcdlpfs", **argv))
eprintf("invalid type %c for -type primary\n", **argv);
extra->i = **argv;
return argv;
}
static char **
get_n_arg(char *argv[], union extra *extra)
{
struct narg *n = extra->p = emalloc(sizeof(*n));
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fill_narg(*argv, n);
return argv;
}
static char **
get_user_arg(char *argv[], union extra *extra)
{
char *end;
struct passwd *p = getpwnam(*argv);
if (p) {
extra->i = p->pw_uid;
} else {
extra->i = strtol(*argv, &end, 10);
if (end == *argv || *end)
eprintf("unknown user '%s'\n", *argv);
}
return argv;
}
static char **
get_group_arg(char *argv[], union extra *extra)
{
char *end;
struct group *g = getgrnam(*argv);
if (g) {
extra->i = g->gr_gid;
} else {
extra->i = strtol(*argv, &end, 10);
if (end == *argv || *end)
eprintf("unknown group '%s'\n", *argv);
}
return argv;
}
static char **
get_size_arg(char *argv[], union extra *extra)
{
char *p = *argv + strlen(*argv);
struct sizearg *s = extra->p = emalloc(sizeof(*s));
/* if the number is followed by 'c', the size will by in bytes */
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if ((s->bytes = (p > *argv && *--p == 'c')))
*p = '\0';
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fill_narg(*argv, &s->n);
return argv;
}
static char **
get_exec_arg(char *argv[], union extra *extra)
{
char **arg, **new, ***braces;
int nbraces = 0;
struct execarg *e = extra->p = emalloc(sizeof(*e));
for (arg = argv; *arg; arg++)
if (!strcmp(*arg, ";"))
break;
else if (arg > argv && !strcmp(*(arg - 1), "{}") && !strcmp(*arg, "+"))
break;
else if (!strcmp(*arg, "{}"))
nbraces++;
if (!*arg)
eprintf("no terminating ; or {} + for -exec primary\n");
e->isplus = **arg == '+';
*arg = NULL;
if (e->isplus) {
*(arg - 1) = NULL; /* don't need the {} in there now */
e->u.p.arglen = e->u.p.filelen = 0;
e->u.p.first = e->u.p.next = arg - argv - 1;
e->u.p.cap = (arg - argv) * 2;
e->argv = ereallocarray(NULL, e->u.p.cap, sizeof(*e->argv));
for (arg = argv, new = e->argv; *arg; arg++, new++) {
*new = *arg;
e->u.p.arglen += strlen(*arg) + 1 + sizeof(*arg);
}
arg++; /* due to our extra NULL */
} else {
e->argv = argv;
e->u.s.braces = ereallocarray(NULL, ++nbraces, sizeof(*e->u.s.braces)); /* ++ for NULL */
for (arg = argv, braces = e->u.s.braces; *arg; arg++)
if (!strcmp(*arg, "{}"))
*braces++ = arg;
}
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gflags.print = 0;
return arg;
}
static char **
get_ok_arg(char *argv[], union extra *extra)
{
char **arg, ***braces;
int nbraces = 0;
struct okarg *o = extra->p = emalloc(sizeof(*o));
for (arg = argv; *arg; arg++)
if (!strcmp(*arg, ";"))
break;
else if (!strcmp(*arg, "{}"))
nbraces++;
if (!*arg)
eprintf("no terminating ; for -ok primary\n");
*arg = NULL;
o->argv = argv;
o->braces = ereallocarray(NULL, ++nbraces, sizeof(*o->braces));
for (arg = argv, braces = o->braces; *arg; arg++)
if (!strcmp(*arg, "{}"))
*braces++ = arg;
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gflags.print = 0;
return arg;
}
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static char **
get_print_arg(char *argv[], union extra *extra)
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{
gflags.print = 0;
return argv;
}
/* FIXME: ignoring nanoseconds */
static char **
get_newer_arg(char *argv[], union extra *extra)
{
struct stat st;
if (stat(*argv, &st))
eprintf("failed to stat '%s':", *argv);
extra->i = st.st_mtime;
return argv;
}
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static char **
get_depth_arg(char *argv[], union extra *extra)
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{
gflags.depth = 1;
return argv;
}
/*
* Freeargs
*/
static void
free_extra(union extra extra)
{
free(extra.p);
}
static void
free_exec_arg(union extra extra)
{
int status;
pid_t pid;
char **arg;
struct execarg *e = extra.p;
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if (!e->isplus) {
free(e->u.s.braces);
} else {
e->argv[e->u.p.next] = NULL;
/* if we have files, do the last exec */
if (e->u.p.first != e->u.p.next) {
switch((pid = fork())) {
case -1:
eprintf("fork:");
case 0:
execvp(*e->argv, e->argv);
weprintf("exec %s failed:", *e->argv);
_exit(1);
}
waitpid(pid, &status, 0);
gflags.ret = gflags.ret || status;
}
for (arg = e->argv + e->u.p.first; *arg; arg++)
free(*arg);
free(e->argv);
}
free(e);
}
static void
free_ok_arg(union extra extra)
{
struct okarg *o = extra.p;
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free(o->braces);
free(o);
}
/*
* Parsing/Building/Running
*/
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static void
fill_narg(char *s, struct narg *n)
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{
char *end;
switch (*s) {
case '+': n->cmp = cmp_gt; s++; break;
case '-': n->cmp = cmp_lt; s++; break;
default : n->cmp = cmp_eq; break;
}
n->n = strtol(s, &end, 10);
if (end == s || *end)
eprintf("bad number '%s'\n", s);
}
static struct pri_info *
find_primary(char *name)
{
struct pri_info *p;
for (p = primaries; p->name; p++)
if (!strcmp(name, p->name))
return p;
return NULL;
}
static struct op_info *
find_op(char *name)
{
struct op_info *o;
for (o = ops; o->name; o++)
if (!strcmp(name, o->name))
return o;
return NULL;
}
/* given the expression from the command line
* 1) convert arguments from strings to tok and place in an array duplicating
* the infix expression given, inserting "-a" where it was omitted
* 2) allocate an array to hold the correct number of tok, and convert from
* infix to rpn (using shunting-yard), add -a and -print if necessary
* 3) evaluate the rpn filling in left and right pointers to create an
* expression tree (tok are still all contained in the rpn array, just
* pointing at eachother)
*/
static void
parse(int argc, char **argv)
{
struct tok infix[2 * argc + 1], *stack[argc], *tok, *rpn, *out, **top;
struct op_info *op;
struct pri_info *pri;
char **arg;
int lasttype = -1;
size_t ntok = 0;
struct tok and = { .u.oinfo = find_op("-a"), .type = AND };
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gflags.print = 1;
/* convert argv to infix expression of tok, inserting in *tok */
for (arg = argv, tok = infix; *arg; arg++, tok++) {
pri = find_primary(*arg);
if (pri) { /* token is a primary, fill out tok and get arguments */
if (lasttype == PRIM || lasttype == RPAR) {
*tok++ = and;
ntok++;
}
if (pri->getarg) {
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if (pri->narg && !*++arg)
eprintf("no argument for primary %s\n", pri->name);
arg = pri->getarg(arg, &tok->extra);
}
tok->u.pinfo = pri;
tok->type = PRIM;
} else if ((op = find_op(*arg))) { /* token is an operator */
if (lasttype == LPAR && op->type == RPAR)
eprintf("empty parens\n");
if (lasttype == PRIM && op->type == NOT) { /* need another implicit -a */
*tok++ = and;
ntok++;
}
tok->type = op->type;
tok->u.oinfo = op;
} else { /* token is neither primary nor operator, must be path in the wrong place */
eprintf("paths must precede expression: %s\n", *arg);
}
if (tok->type != LPAR && tok->type != RPAR)
ntok++; /* won't have parens in rpn */
lasttype = tok->type;
}
tok->type = END;
ntok++;
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if (gflags.print && (arg != argv)) /* need to add -a -print (not just -print) */
gflags.print++;
/* use shunting-yard to convert from infix to rpn
* https://en.wikipedia.org/wiki/Shunting-yard_algorithm
* read from infix, resulting rpn ends up in rpn, next position in rpn is out
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* push operators onto stack, next position in stack is top */
rpn = ereallocarray(NULL, ntok + gflags.print, sizeof(*rpn));
for (tok = infix, out = rpn, top = stack; tok->type != END; tok++) {
switch (tok->type) {
case PRIM: *out++ = *tok; break;
case LPAR: *top++ = tok; break;
case RPAR:
while (top-- > stack && (*top)->type != LPAR)
*out++ = **top;
if (top < stack)
eprintf("extra )\n");
break;
default:
/* this expression can be simplified, but I decided copy the
* verbage from the wikipedia page in order to more clearly explain
* what's going on */
while (top-- > stack &&
(( tok->u.oinfo->lassoc && tok->u.oinfo->prec <= (*top)->u.oinfo->prec) ||
(!tok->u.oinfo->lassoc && tok->u.oinfo->prec < (*top)->u.oinfo->prec)))
*out++ = **top;
/* top now points to either an operator we didn't pop, or stack[-1]
* either way we need to increment it before using it, then
* increment again so the stack works */
top++;
*top++ = tok;
break;
}
}
while (top-- > stack) {
if ((*top)->type == LPAR)
eprintf("extra (\n");
*out++ = **top;
}
/* if there was no expression, use -print
* if there was an expression but no -print, -exec, or -ok, add -a -print
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* in rpn, not infix */
if (gflags.print)
*out++ = (struct tok){ .u.pinfo = find_primary("-print"), .type = PRIM };
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if (gflags.print == 2)
*out++ = and;
out->type = END;
/* rpn now holds all operators and arguments in reverse polish notation
* values are pushed onto stack, operators pop values off stack into left
* and right pointers, pushing operator node back onto stack
* could probably just do this during shunting-yard, but this is simpler
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* code IMO */
for (tok = rpn, top = stack; tok->type != END; tok++) {
if (tok->type == PRIM) {
*top++ = tok;
} else {
if (top - stack < tok->u.oinfo->nargs)
eprintf("insufficient arguments for operator %s\n", tok->u.oinfo->name);
tok->right = *--top;
tok->left = tok->u.oinfo->nargs == 2 ? *--top : NULL;
*top++ = tok;
}
}
if (--top != stack)
eprintf("extra arguments\n");
toks = rpn;
root = *top;
}
/* for a primary, run and return result
* for an operator evaluate the left side of the tree, decide whether or not to
* evaluate the right based on the short-circuit boolean logic, return result
* NOTE: operator NOT has NULL left side, expression on right side
*/
static int
eval(struct tok *tok, struct arg *arg)
{
int ret;
if (!tok)
return 0;
if (tok->type == PRIM) {
arg->extra = tok->extra;
return tok->u.pinfo->func(arg);
}
ret = eval(tok->left, arg);
if ((tok->type == AND && ret) || (tok->type == OR && !ret) || tok->type == NOT)
ret = eval(tok->right, arg);
return ret ^ (tok->type == NOT);
}
/* evaluate path, if it's a directory iterate through directory entries and
* recurse
*/
static void
find(char *path, struct findhist *hist)
{
struct stat st;
DIR *dir;
struct dirent *de;
struct findhist *f, cur;
size_t len = strlen(path) + 2; /* null and '/' */
struct arg arg = { path, &st, { NULL } };
if ((gflags.l || (gflags.h && !hist) ? stat(path, &st) : lstat(path, &st)) < 0) {
weprintf("failed to stat %s:", path);
return;
}
gflags.prune = 0;
/* don't eval now iff we will hit the eval at the bottom which means
* 1. we are a directory 2. we have -depth 3. we don't have -xdev or we are
* on same device (so most of the time we eval here) */
if (!S_ISDIR(st.st_mode) ||
!gflags.depth ||
(gflags.xdev && hist && st.st_dev != hist->dev))
eval(root, &arg);
if (!S_ISDIR(st.st_mode) ||
gflags.prune ||
(gflags.xdev && hist && st.st_dev != hist->dev))
return;
for (f = hist; f; f = f->next) {
if (f->dev == st.st_dev && f->ino == st.st_ino) {
weprintf("loop detected '%s' is '%s'\n", path, f->path);
return;
}
}
cur.next = hist;
cur.path = path;
cur.dev = st.st_dev;
cur.ino = st.st_ino;
if (!(dir = opendir(path))) {
weprintf("failed to opendir %s:", path);
/* should we just ignore this since we hit an error? */
if (gflags.depth)
eval(root, &arg);
return;
}
/* FIXME: check errno to see if we are done or encountered an error? */
while ((de = readdir(dir))) {
size_t pathcap = len + strlen(de->d_name);
char pathbuf[pathcap], *p;
if (!strcmp(de->d_name, ".") || !strcmp(de->d_name, ".."))
continue;
p = pathbuf + estrlcpy(pathbuf, path, pathcap);
if (*--p != '/')
estrlcat(pathbuf, "/", pathcap);
estrlcat(pathbuf, de->d_name, pathcap);
find(pathbuf, &cur);
}
closedir(dir); /* check return value? */
if (gflags.depth)
eval(root, &arg);
}
static void
usage(void)
{
eprintf("usage: %s [-H|-L] path... [expression...]\n", argv0);
}
int
main(int argc, char **argv)
{
char **paths;
int npaths;
struct tok *t;
ARGBEGIN {
case 'H': gflags.l = !(gflags.h = 1); break;
case 'L': gflags.h = !(gflags.l = 1); break;
default : usage();
} ARGEND;
paths = argv;
for (; *argv && **argv != '-' && strcmp(*argv, "!") && strcmp(*argv, "("); argv++)
;
if (!(npaths = argv - paths))
eprintf("must specify a path\n");
parse(argc - npaths, argv);
/* calculate number of bytes in environ for -exec {} + ARG_MAX avoidance
* libc implementation defined whether null bytes, pointers, and alignment
* are counted, so count them */
for (argv = environ; *argv; argv++)
envlen += strlen(*argv) + 1 + sizeof(*argv);
if ((argmax = sysconf(_SC_ARG_MAX)) == (size_t)-1)
argmax = _POSIX_ARG_MAX;
if (clock_gettime(CLOCK_REALTIME, &start) < 0)
weprintf("clock_gettime() failed:");
while (npaths--)
find(*paths, NULL);
for (t = toks; t->type != END; t++)
if (t->type == PRIM && t->u.pinfo->freearg)
t->u.pinfo->freearg(t->extra);
free(toks);
Add *fshut() functions to properly flush file streams This has been a known issue for a long time. Example: printf "word" > /dev/full wouldn't report there's not enough space on the device. This is due to the fact that every libc has internal buffers for stdout which store fragments of written data until they reach a certain size or on some callback to flush them all at once to the kernel. You can force the libc to flush them with fflush(). In case flushing fails, you can check the return value of fflush() and report an error. However, previously, sbase didn't have such checks and without fflush(), the libc silently flushes the buffers on exit without checking the errors. No offense, but there's no way for the libc to report errors in the exit- condition. GNU coreutils solve this by having onexit-callbacks to handle the flushing and report issues, but they have obvious deficiencies. After long discussions on IRC, we came to the conclusion that checking the return value of every io-function would be a bit too much, and having a general-purpose fclose-wrapper would be the best way to go. It turned out that fclose() alone is not enough to detect errors. The right way to do it is to fflush() + check ferror on the fp and then to a fclose(). This is what fshut does and that's how it's done before each return. The return value is obviously affected, reporting an error in case a flush or close failed, but also when reading failed for some reason, the error- state is caught. the !!( ... + ...) construction is used to call all functions inside the brackets and not "terminating" on the first. We want errors to be reported, but there's no reason to stop flushing buffers when one other file buffer has issues. Obviously, functionales come before the flush and ret-logic comes after to prevent early exits as well without reporting warnings if there are any. One more advantage of fshut() is that it is even able to report errors on obscure NFS-setups which the other coreutils are unable to detect, because they only check the return-value of fflush() and fclose(), not ferror() as well.
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return !!(fshut(stdin, "<stdin>") + fshut(stdout, "<stdout>")) || gflags.ret;
}