/* See LICENSE file for copyright and license details. */ #include #include #include #include #include #include "util.h" static int intcmp(char *a, char *b) { char *s; int asign = *a == '-' ? -1 : 1; int bsign = *b == '-' ? -1 : 1; if (*a == '-' || *a == '+') a += 1; if (*b == '-' || *b == '+') b += 1; if (!*a || !*b) goto noint; for (s = a; *s; s++) if (!isdigit(*s)) goto noint; for (s = b; *s; s++) if (!isdigit(*s)) goto noint; while (*a == '0') a++; while (*b == '0') b++; asign *= !!*a; bsign *= !!*b; if (asign != bsign) return asign < bsign ? -1 : 1; else if (strlen(a) != strlen(b)) return asign * (strlen(a) < strlen(b) ? -1 : 1); else return asign * strcmp(a, b); noint: enprintf(2, "expected integer operands\n"); return 0; /* not reached */ } static int mtimecmp(struct stat *buf1, struct stat *buf2) { if (buf1->st_mtime < buf2->st_mtime) return -1; if (buf1->st_mtime > buf2->st_mtime) return +1; #ifdef st_mtime if (buf1->st_mtim.tv_nsec < buf2->st_mtim.tv_nsec) return -1; if (buf1->st_mtim.tv_nsec > buf2->st_mtim.tv_nsec) return +1; #endif return 0; } static int unary_b(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISBLK (buf.st_mode); } static int unary_c(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISCHR (buf.st_mode); } static int unary_d(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISDIR (buf.st_mode); } static int unary_f(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISREG (buf.st_mode); } static int unary_g(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISGID & buf.st_mode ; } static int unary_h(char *s) { struct stat buf; if (lstat(s, &buf)) return 0; return S_ISLNK (buf.st_mode); } static int unary_k(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISVTX & buf.st_mode ; } static int unary_p(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISFIFO (buf.st_mode); } static int unary_S(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISSOCK (buf.st_mode); } static int unary_s(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return buf.st_size ; } static int unary_u(char *s) { struct stat buf; if ( stat(s, &buf)) return 0; return S_ISUID & buf.st_mode ; } static int unary_n(char *s) { return *s; } static int unary_z(char *s) { return !*s; } static int unary_e(char *s) { return !faccessat(AT_FDCWD, s, F_OK, AT_EACCESS); } static int unary_r(char *s) { return !faccessat(AT_FDCWD, s, R_OK, AT_EACCESS); } static int unary_w(char *s) { return !faccessat(AT_FDCWD, s, W_OK, AT_EACCESS); } static int unary_x(char *s) { return !faccessat(AT_FDCWD, s, X_OK, AT_EACCESS); } static int unary_t(char *s) { int fd = enstrtonum(2, s, 0, INT_MAX); return isatty(fd); } static int binary_se(char *s1, char *s2) { return !strcmp(s1, s2); } static int binary_sn(char *s1, char *s2) { return strcmp(s1, s2); } static int binary_eq(char *s1, char *s2) { return intcmp(s1, s2) == 0; } static int binary_ne(char *s1, char *s2) { return intcmp(s1, s2) != 0; } static int binary_gt(char *s1, char *s2) { return intcmp(s1, s2) > 0; } static int binary_ge(char *s1, char *s2) { return intcmp(s1, s2) >= 0; } static int binary_lt(char *s1, char *s2) { return intcmp(s1, s2) < 0; } static int binary_le(char *s1, char *s2) { return intcmp(s1, s2) <= 0; } static int binary_ef(char *s1, char *s2) { struct stat buf1, buf2; if (stat(s1, &buf1) || stat(s2, &buf2)) return 0; return buf1.st_dev == buf2.st_dev && buf1.st_ino == buf2.st_ino; } static int binary_ot(char *s1, char *s2) { struct stat buf1, buf2; if (stat(s1, &buf1) || stat(s2, &buf2)) return 0; return mtimecmp(&buf1, &buf2) < 0; } static int binary_nt(char *s1, char *s2) { struct stat buf1, buf2; if (stat(s1, &buf1) || stat(s2, &buf2)) return 0; return mtimecmp(&buf1, &buf2) > 0; } struct test { char *name; union { int (*u)(char *); int (*b)(char *, char *); } func; }; static struct test unary[] = { { "-b", { .u = unary_b } }, { "-c", { .u = unary_c } }, { "-d", { .u = unary_d } }, { "-e", { .u = unary_e } }, { "-f", { .u = unary_f } }, { "-g", { .u = unary_g } }, { "-h", { .u = unary_h } }, { "-k", { .u = unary_k } }, { "-L", { .u = unary_h } }, { "-n", { .u = unary_n } }, { "-p", { .u = unary_p } }, { "-r", { .u = unary_r } }, { "-S", { .u = unary_S } }, { "-s", { .u = unary_s } }, { "-t", { .u = unary_t } }, { "-u", { .u = unary_u } }, { "-w", { .u = unary_w } }, { "-x", { .u = unary_x } }, { "-z", { .u = unary_z } }, { NULL }, }; static struct test binary[] = { { "=" , { .b = binary_se } }, { "!=" , { .b = binary_sn } }, { "-eq", { .b = binary_eq } }, { "-ne", { .b = binary_ne } }, { "-gt", { .b = binary_gt } }, { "-ge", { .b = binary_ge } }, { "-lt", { .b = binary_lt } }, { "-le", { .b = binary_le } }, { "-ef", { .b = binary_ef } }, { "-ot", { .b = binary_ot } }, { "-nt", { .b = binary_nt } }, { NULL }, }; static struct test * find_test(struct test *tests, char *name) { struct test *t; for (t = tests; t->name; t++) if (!strcmp(t->name, name)) return t; return NULL; } static int noarg(char *argv[]) { return 0; } static int onearg(char *argv[]) { return unary_n(argv[0]); } static int twoarg(char *argv[]) { struct test *t; if (!strcmp(argv[0], "!")) return !onearg(argv + 1); if ((t = find_test(unary, *argv))) return t->func.u(argv[1]); enprintf(2, "bad unary test %s\n", argv[0]); return 0; /* not reached */ } static int threearg(char *argv[]) { struct test *t = find_test(binary, argv[1]); if (t) return t->func.b(argv[0], argv[2]); if (!strcmp(argv[0], "!")) return !twoarg(argv + 1); enprintf(2, "bad binary test %s\n", argv[1]); return 0; /* not reached */ } static int fourarg(char *argv[]) { if (!strcmp(argv[0], "!")) return !threearg(argv + 1); enprintf(2, "too many arguments\n"); return 0; /* not reached */ } int main(int argc, char *argv[]) { int (*narg[])(char *[]) = { noarg, onearg, twoarg, threearg, fourarg }; size_t len; argv0 = *argv, argv0 ? (argc--, argv++) : (void *)0; len = argv0 ? strlen(argv0) : 0; if (len && argv0[--len] == '[' && (!len || argv0[--len] == '/') && strcmp(argv[--argc], "]")) enprintf(2, "no matching ]\n"); if (argc > 4) enprintf(2, "too many arguments\n"); return !narg[argc](argv); }