hush/shell/hush.c
2009-04-15 23:29:44 +00:00

6812 lines
181 KiB
C

/* vi: set sw=4 ts=4: */
/*
* A prototype Bourne shell grammar parser.
* Intended to follow the original Thompson and Ritchie
* "small and simple is beautiful" philosophy, which
* incidentally is a good match to today's BusyBox.
*
* Copyright (C) 2000,2001 Larry Doolittle <larry@doolittle.boa.org>
* Copyright (C) 2008,2009 Denys Vlasenko <vda.linux@googlemail.com>
*
* Credits:
* The parser routines proper are all original material, first
* written Dec 2000 and Jan 2001 by Larry Doolittle. The
* execution engine, the builtins, and much of the underlying
* support has been adapted from busybox-0.49pre's lash, which is
* Copyright (C) 1999-2004 by Erik Andersen <andersen@codepoet.org>
* written by Erik Andersen <andersen@codepoet.org>. That, in turn,
* is based in part on ladsh.c, by Michael K. Johnson and Erik W.
* Troan, which they placed in the public domain. I don't know
* how much of the Johnson/Troan code has survived the repeated
* rewrites.
*
* Other credits:
* o_addchr derived from similar w_addchar function in glibc-2.2.
* parse_redirect, redirect_opt_num, and big chunks of main
* and many builtins derived from contributions by Erik Andersen.
* Miscellaneous bugfixes from Matt Kraai.
*
* There are two big (and related) architecture differences between
* this parser and the lash parser. One is that this version is
* actually designed from the ground up to understand nearly all
* of the Bourne grammar. The second, consequential change is that
* the parser and input reader have been turned inside out. Now,
* the parser is in control, and asks for input as needed. The old
* way had the input reader in control, and it asked for parsing to
* take place as needed. The new way makes it much easier to properly
* handle the recursion implicit in the various substitutions, especially
* across continuation lines.
*
* POSIX syntax not implemented:
* aliases
* <(list) and >(list) Process Substitution
* Tilde Expansion
*
* Bash stuff (maybe optionally enable?):
* &> and >& redirection of stdout+stderr
* Brace expansion
* reserved words: [[ ]] function select
* substrings ${var:1:5}
*
* TODOs:
* grep for "TODO" and fix (some of them are easy)
* change { and } from special chars to reserved words
* builtins: return, ulimit
* follow IFS rules more precisely, including update semantics
* figure out what to do with backslash-newline
* continuation lines, both explicit and implicit - done?
* SIGHUP handling
* separate job control from interactiveness
* (testcase: booting with init=/bin/hush does not show prompt (2009-04))
*
* Licensed under the GPL v2 or later, see the file LICENSE in this tarball.
*/
#include "busybox.h" /* for APPLET_IS_NOFORK/NOEXEC */
#include <glob.h>
/* #include <dmalloc.h> */
#if ENABLE_HUSH_CASE
# include <fnmatch.h>
#endif
#include "math.h"
#include "match.h"
#ifndef PIPE_BUF
# define PIPE_BUF 4096 /* amount of buffering in a pipe */
#endif
/* Debug build knobs */
#define LEAK_HUNTING 0
#define BUILD_AS_NOMMU 0
/* Enable/disable sanity checks. Ok to enable in production,
* only adds a bit of bloat. Set to >1 to get non-production level verbosity.
* Keeping 1 for now even in released versions.
*/
#define HUSH_DEBUG 1
#if BUILD_AS_NOMMU
# undef BB_MMU
# undef USE_FOR_NOMMU
# undef USE_FOR_MMU
# define BB_MMU 0
# define USE_FOR_NOMMU(...) __VA_ARGS__
# define USE_FOR_MMU(...)
#endif
#if defined SINGLE_APPLET_MAIN
/* STANDALONE does not make sense, and won't compile */
# undef CONFIG_FEATURE_SH_STANDALONE
# undef ENABLE_FEATURE_SH_STANDALONE
# undef USE_FEATURE_SH_STANDALONE
# define SKIP_FEATURE_SH_STANDALONE(...) __VA_ARGS__
# define ENABLE_FEATURE_SH_STANDALONE 0
# define USE_FEATURE_SH_STANDALONE(...)
# define SKIP_FEATURE_SH_STANDALONE(...) __VA_ARGS__
#endif
#if !ENABLE_HUSH_INTERACTIVE
# undef ENABLE_FEATURE_EDITING
# define ENABLE_FEATURE_EDITING 0
# undef ENABLE_FEATURE_EDITING_FANCY_PROMPT
# define ENABLE_FEATURE_EDITING_FANCY_PROMPT 0
#endif
/* Do we support ANY keywords? */
#if ENABLE_HUSH_IF || ENABLE_HUSH_LOOPS || ENABLE_HUSH_CASE
# define HAS_KEYWORDS 1
# define IF_HAS_KEYWORDS(...) __VA_ARGS__
# define IF_HAS_NO_KEYWORDS(...)
#else
# define HAS_KEYWORDS 0
# define IF_HAS_KEYWORDS(...)
# define IF_HAS_NO_KEYWORDS(...) __VA_ARGS__
#endif
/* If you comment out one of these below, it will be #defined later
* to perform debug printfs to stderr: */
#define debug_printf(...) do {} while (0)
/* Finer-grained debug switches */
#define debug_printf_parse(...) do {} while (0)
#define debug_print_tree(a, b) do {} while (0)
#define debug_printf_exec(...) do {} while (0)
#define debug_printf_env(...) do {} while (0)
#define debug_printf_jobs(...) do {} while (0)
#define debug_printf_expand(...) do {} while (0)
#define debug_printf_glob(...) do {} while (0)
#define debug_printf_list(...) do {} while (0)
#define debug_printf_subst(...) do {} while (0)
#define debug_printf_clean(...) do {} while (0)
#define ERR_PTR ((void*)(long)1)
#define JOB_STATUS_FORMAT "[%d] %-22s %.40s\n"
#define SPECIAL_VAR_SYMBOL 3
static const char hush_version_str[] ALIGN1 = "HUSH_VERSION="BB_VER;
/* This supports saving pointers malloced in vfork child,
* to be freed in the parent.
*/
#if !BB_MMU
typedef struct nommu_save_t {
char **new_env;
char **old_env;
char **argv;
char **argv_from_re_execing;
} nommu_save_t;
#endif
/* The descrip member of this structure is only used to make
* debugging output pretty */
static const struct {
int mode;
signed char default_fd;
char descrip[3];
} redir_table[] = {
{ 0, 0, "??" },
{ O_RDONLY, 0, "<" },
{ O_CREAT|O_TRUNC|O_WRONLY, 1, ">" },
{ O_CREAT|O_APPEND|O_WRONLY, 1, ">>" },
{ O_RDONLY, 0, "<<" },
{ O_CREAT|O_RDWR, 1, "<>" },
/* Should not be needed. Bogus default_fd helps in debugging */
/* { O_RDONLY, 77, "<<" }, */
};
typedef enum reserved_style {
RES_NONE = 0,
#if ENABLE_HUSH_IF
RES_IF ,
RES_THEN ,
RES_ELIF ,
RES_ELSE ,
RES_FI ,
#endif
#if ENABLE_HUSH_LOOPS
RES_FOR ,
RES_WHILE ,
RES_UNTIL ,
RES_DO ,
RES_DONE ,
#endif
#if ENABLE_HUSH_LOOPS || ENABLE_HUSH_CASE
RES_IN ,
#endif
#if ENABLE_HUSH_CASE
RES_CASE ,
/* two pseudo-keywords support contrived "case" syntax: */
RES_MATCH , /* "word)" */
RES_CASEI , /* "this command is inside CASE" */
RES_ESAC ,
#endif
RES_XXXX ,
RES_SNTX
} reserved_style;
typedef struct o_string {
char *data;
int length; /* position where data is appended */
int maxlen;
/* Protect newly added chars against globbing
* (by prepending \ to *, ?, [, \) */
smallint o_escape;
smallint o_glob;
/* At least some part of the string was inside '' or "",
* possibly empty one: word"", wo''rd etc. */
smallint o_quoted;
smallint has_empty_slot;
smallint o_assignment; /* 0:maybe, 1:yes, 2:no */
} o_string;
enum {
MAYBE_ASSIGNMENT = 0,
DEFINITELY_ASSIGNMENT = 1,
NOT_ASSIGNMENT = 2,
WORD_IS_KEYWORD = 3, /* not assigment, but next word may be: "if v=xyz cmd;" */
};
/* Used for initialization: o_string foo = NULL_O_STRING; */
#define NULL_O_STRING { NULL }
/* I can almost use ordinary FILE*. Is open_memstream() universally
* available? Where is it documented? */
typedef struct in_str {
const char *p;
/* eof_flag=1: last char in ->p is really an EOF */
char eof_flag; /* meaningless if ->p == NULL */
char peek_buf[2];
#if ENABLE_HUSH_INTERACTIVE
smallint promptme;
smallint promptmode; /* 0: PS1, 1: PS2 */
#endif
FILE *file;
int (*get) (struct in_str *);
int (*peek) (struct in_str *);
} in_str;
#define i_getch(input) ((input)->get(input))
#define i_peek(input) ((input)->peek(input))
struct redir_struct {
struct redir_struct *next;
char *rd_filename; /* filename */
int rd_fd; /* fd to redirect */
/* fd to redirect to, or -3 if rd_fd is to be closed (n>&-) */
int rd_dup;
smallint rd_type; /* (enum redir_type) */
/* note: for heredocs, rd_filename contains heredoc delimiter,
* and subsequently heredoc itself; and rd_dup is a bitmask:
* 1: do we need to trim leading tabs?
* 2: is heredoc quoted (<<'delim' syntax) ?
*/
};
typedef enum redir_type {
REDIRECT_INVALID = 0,
REDIRECT_INPUT = 1,
REDIRECT_OVERWRITE = 2,
REDIRECT_APPEND = 3,
REDIRECT_HEREDOC = 4,
REDIRECT_IO = 5,
REDIRECT_HEREDOC2 = 6, /* REDIRECT_HEREDOC after heredoc is loaded */
REDIRFD_CLOSE = -3,
REDIRFD_SYNTAX_ERR = -2,
REDIRFD_TO_FILE = -1,
/* otherwise, rd_fd is redirected to rd_dup */
HEREDOC_SKIPTABS = 1,
HEREDOC_QUOTED = 2,
} redir_type;
struct command {
pid_t pid; /* 0 if exited */
int assignment_cnt; /* how many argv[i] are assignments? */
smallint is_stopped; /* is the command currently running? */
smallint grp_type; /* GRP_xxx */
#define GRP_NORMAL 0
#define GRP_SUBSHELL 1
#if ENABLE_HUSH_FUNCTIONS
# define GRP_FUNCTION 2
#endif
struct pipe *group; /* if non-NULL, this "command" is { list },
* ( list ), or a compound statement */
#if !BB_MMU
char *group_as_string;
#endif
#if ENABLE_HUSH_FUNCTIONS
struct function *child_func;
/* This field is used to prevent a bug here:
* while...do f1() {a;}; f1; f1 {b;}; f1; done
* When we execute "f1() {a;}" cmd, we create new function and clear
* cmd->group, cmd->group_as_string, cmd->argv[0].
* when we execute "f1 {b;}", we notice that f1 exists,
* and that it's "parent cmd" struct is still "alive",
* we put those fields back into cmd->xxx
* (struct function has ->parent_cmd ptr to facilitate that).
* When we loop back, we can execute "f1() {a;}" again and set f1 correctly.
* Without this trick, loop would execute a;b;b;b;...
* instead of correct sequence a;b;a;b;...
* When command is freed, it severs the link
* (sets ->child_func->parent_cmd to NULL).
*/
#endif
char **argv; /* command name and arguments */
/* argv vector may contain variable references (^Cvar^C, ^C0^C etc)
* and on execution these are substituted with their values.
* Substitution can make _several_ words out of one argv[n]!
* Example: argv[0]=='.^C*^C.' here: echo .$*.
* References of the form ^C`cmd arg^C are `cmd arg` substitutions.
*/
struct redir_struct *redirects; /* I/O redirections */
};
struct pipe {
struct pipe *next;
int num_cmds; /* total number of commands in pipe */
int alive_cmds; /* number of commands running (not exited) */
int stopped_cmds; /* number of commands alive, but stopped */
#if ENABLE_HUSH_JOB
int jobid; /* job number */
pid_t pgrp; /* process group ID for the job */
char *cmdtext; /* name of job */
#endif
struct command *cmds; /* array of commands in pipe */
smallint followup; /* PIPE_BG, PIPE_SEQ, PIPE_OR, PIPE_AND */
IF_HAS_KEYWORDS(smallint pi_inverted;) /* "! cmd | cmd" */
IF_HAS_KEYWORDS(smallint res_word;) /* needed for if, for, while, until... */
};
typedef enum pipe_style {
PIPE_SEQ = 1,
PIPE_AND = 2,
PIPE_OR = 3,
PIPE_BG = 4,
} pipe_style;
/* This holds pointers to the various results of parsing */
struct parse_context {
/* linked list of pipes */
struct pipe *list_head;
/* last pipe (being constructed right now) */
struct pipe *pipe;
/* last command in pipe (being constructed right now) */
struct command *command;
/* last redirect in command->redirects list */
struct redir_struct *pending_redirect;
#if !BB_MMU
o_string as_string;
#endif
#if HAS_KEYWORDS
smallint ctx_res_w;
smallint ctx_inverted; /* "! cmd | cmd" */
#if ENABLE_HUSH_CASE
smallint ctx_dsemicolon; /* ";;" seen */
#endif
/* bitmask of FLAG_xxx, for figuring out valid reserved words */
int old_flag;
/* group we are enclosed in:
* example: "if pipe1; pipe2; then pipe3; fi"
* when we see "if" or "then", we malloc and copy current context,
* and make ->stack point to it. then we parse pipeN.
* when closing "then" / fi" / whatever is found,
* we move list_head into ->stack->command->group,
* copy ->stack into current context, and delete ->stack.
* (parsing of { list } and ( list ) doesn't use this method)
*/
struct parse_context *stack;
#endif
};
/* On program start, environ points to initial environment.
* putenv adds new pointers into it, unsetenv removes them.
* Neither of these (de)allocates the strings.
* setenv allocates new strings in malloc space and does putenv,
* and thus setenv is unusable (leaky) for shell's purposes */
#define setenv(...) setenv_is_leaky_dont_use()
struct variable {
struct variable *next;
char *varstr; /* points to "name=" portion */
int max_len; /* if > 0, name is part of initial env; else name is malloced */
smallint flg_export; /* putenv should be done on this var */
smallint flg_read_only;
};
enum {
BC_BREAK = 1,
BC_CONTINUE = 2,
};
#if ENABLE_HUSH_FUNCTIONS
struct function {
struct function *next;
char *name;
struct command *parent_cmd;
struct pipe *body;
#if !BB_MMU
char *body_as_string;
#endif
};
#endif
/* "Globals" within this file */
/* Sorted roughly by size (smaller offsets == smaller code) */
struct globals {
#if ENABLE_HUSH_INTERACTIVE
/* 'interactive_fd' is a fd# open to ctty, if we have one
* _AND_ if we decided to act interactively */
int interactive_fd;
const char *PS1;
const char *PS2;
#define G_interactive_fd (G.interactive_fd)
#else
#define G_interactive_fd 0
#endif
#if ENABLE_FEATURE_EDITING
line_input_t *line_input_state;
#endif
pid_t root_pid;
pid_t last_bg_pid;
#if ENABLE_HUSH_JOB
int run_list_level;
pid_t saved_tty_pgrp;
int last_jobid;
struct pipe *job_list;
struct pipe *toplevel_list;
#endif
smallint flag_SIGINT;
#if ENABLE_HUSH_LOOPS
smallint flag_break_continue;
#endif
smallint fake_mode;
smallint exiting; /* used to prevent EXIT trap recursion */
/* These four support $?, $#, and $1 */
smalluint last_exitcode;
/* are global_argv and global_argv[1..n] malloced? (note: not [0]) */
smalluint global_args_malloced;
/* how many non-NULL argv's we have. NB: $# + 1 */
int global_argc;
char **global_argv;
#if !BB_MMU
char *argv0_for_re_execing;
#endif
#if ENABLE_HUSH_LOOPS
unsigned depth_break_continue;
unsigned depth_of_loop;
#endif
const char *ifs;
const char *cwd;
struct variable *top_var; /* = &G.shell_ver (set in main()) */
struct variable shell_ver;
#if ENABLE_HUSH_FUNCTIONS
struct function *top_func;
#endif
/* Signal and trap handling */
// unsigned count_SIGCHLD;
// unsigned handled_SIGCHLD;
/* which signals have non-DFL handler (even with no traps set)? */
unsigned non_DFL_mask;
char **traps; /* char *traps[NSIG] */
sigset_t blocked_set;
sigset_t inherited_set;
#if HUSH_DEBUG
unsigned long memleak_value;
int debug_indent;
#endif
char user_input_buf[ENABLE_FEATURE_EDITING ? BUFSIZ : 2];
};
#define G (*ptr_to_globals)
/* Not #defining name to G.name - this quickly gets unwieldy
* (too many defines). Also, I actually prefer to see when a variable
* is global, thus "G." prefix is a useful hint */
#define INIT_G() do { \
SET_PTR_TO_GLOBALS(xzalloc(sizeof(G))); \
} while (0)
/* Function prototypes for builtins */
static int builtin_cd(char **argv);
static int builtin_echo(char **argv);
static int builtin_eval(char **argv);
static int builtin_exec(char **argv);
static int builtin_exit(char **argv);
static int builtin_export(char **argv);
#if ENABLE_HUSH_JOB
static int builtin_fg_bg(char **argv);
static int builtin_jobs(char **argv);
#endif
#if ENABLE_HUSH_HELP
static int builtin_help(char **argv);
#endif
#if HUSH_DEBUG
static int builtin_memleak(char **argv);
#endif
static int builtin_pwd(char **argv);
static int builtin_read(char **argv);
static int builtin_set(char **argv);
static int builtin_shift(char **argv);
static int builtin_source(char **argv);
static int builtin_test(char **argv);
static int builtin_trap(char **argv);
static int builtin_true(char **argv);
static int builtin_umask(char **argv);
static int builtin_unset(char **argv);
static int builtin_wait(char **argv);
#if ENABLE_HUSH_LOOPS
static int builtin_break(char **argv);
static int builtin_continue(char **argv);
#endif
/* Table of built-in functions. They can be forked or not, depending on
* context: within pipes, they fork. As simple commands, they do not.
* When used in non-forking context, they can change global variables
* in the parent shell process. If forked, of course they cannot.
* For example, 'unset foo | whatever' will parse and run, but foo will
* still be set at the end. */
struct built_in_command {
const char *cmd;
int (*function)(char **argv);
#if ENABLE_HUSH_HELP
const char *descr;
#define BLTIN(cmd, func, help) { cmd, func, help }
#else
#define BLTIN(cmd, func, help) { cmd, func }
#endif
};
/* For now, echo and test are unconditionally enabled.
* Maybe make it configurable? */
static const struct built_in_command bltins[] = {
BLTIN("." , builtin_source , "Run commands in a file"),
BLTIN(":" , builtin_true , "No-op"),
BLTIN("[" , builtin_test , "Test condition"),
#if ENABLE_HUSH_JOB
BLTIN("bg" , builtin_fg_bg , "Resume a job in the background"),
#endif
#if ENABLE_HUSH_LOOPS
BLTIN("break" , builtin_break , "Exit from a loop"),
#endif
BLTIN("cd" , builtin_cd , "Change directory"),
#if ENABLE_HUSH_LOOPS
BLTIN("continue", builtin_continue, "Start new loop iteration"),
#endif
BLTIN("echo" , builtin_echo , "Write to stdout"),
BLTIN("eval" , builtin_eval , "Construct and run shell command"),
BLTIN("exec" , builtin_exec , "Execute command, don't return to shell"),
BLTIN("exit" , builtin_exit , "Exit"),
BLTIN("export" , builtin_export , "Set environment variable"),
#if ENABLE_HUSH_JOB
BLTIN("fg" , builtin_fg_bg , "Bring job into the foreground"),
#endif
#if ENABLE_HUSH_HELP
BLTIN("help" , builtin_help , "List shell built-in commands"),
#endif
#if ENABLE_HUSH_JOB
BLTIN("jobs" , builtin_jobs , "List active jobs"),
#endif
#if HUSH_DEBUG
BLTIN("memleak" , builtin_memleak , "Debug tool"),
#endif
BLTIN("pwd" , builtin_pwd , "Print current directory"),
BLTIN("read" , builtin_read , "Input environment variable"),
// BLTIN("return" , builtin_return , "Return from a function"),
BLTIN("set" , builtin_set , "Set/unset shell local variables"),
BLTIN("shift" , builtin_shift , "Shift positional parameters"),
BLTIN("test" , builtin_test , "Test condition"),
BLTIN("trap" , builtin_trap , "Trap signals"),
// BLTIN("ulimit" , builtin_return , "Control resource limits"),
BLTIN("umask" , builtin_umask , "Set file creation mask"),
BLTIN("unset" , builtin_unset , "Unset environment variable"),
BLTIN("wait" , builtin_wait , "Wait for process"),
};
/* Debug printouts.
*/
#if HUSH_DEBUG
/* prevent disasters with G.debug_indent < 0 */
# define indent() fprintf(stderr, "%*s", (G.debug_indent * 2) & 0xff, "")
# define debug_enter() (G.debug_indent++)
# define debug_leave() (G.debug_indent--)
#else
# define indent() ((void)0)
# define debug_enter() ((void)0)
# define debug_leave() ((void)0)
#endif
#ifndef debug_printf
# define debug_printf(...) (indent(), fprintf(stderr, __VA_ARGS__))
#endif
#ifndef debug_printf_parse
# define debug_printf_parse(...) (indent(), fprintf(stderr, __VA_ARGS__))
#endif
#ifndef debug_printf_exec
#define debug_printf_exec(...) (indent(), fprintf(stderr, __VA_ARGS__))
#endif
#ifndef debug_printf_env
# define debug_printf_env(...) (indent(), fprintf(stderr, __VA_ARGS__))
#endif
#ifndef debug_printf_jobs
# define debug_printf_jobs(...) (indent(), fprintf(stderr, __VA_ARGS__))
# define DEBUG_JOBS 1
#else
# define DEBUG_JOBS 0
#endif
#ifndef debug_printf_expand
# define debug_printf_expand(...) (indent(), fprintf(stderr, __VA_ARGS__))
# define DEBUG_EXPAND 1
#else
# define DEBUG_EXPAND 0
#endif
#ifndef debug_printf_glob
# define debug_printf_glob(...) (indent(), fprintf(stderr, __VA_ARGS__))
# define DEBUG_GLOB 1
#else
# define DEBUG_GLOB 0
#endif
#ifndef debug_printf_list
# define debug_printf_list(...) (indent(), fprintf(stderr, __VA_ARGS__))
#endif
#ifndef debug_printf_subst
# define debug_printf_subst(...) (indent(), fprintf(stderr, __VA_ARGS__))
#endif
#ifndef debug_printf_clean
# define debug_printf_clean(...) (indent(), fprintf(stderr, __VA_ARGS__))
# define DEBUG_CLEAN 1
#else
# define DEBUG_CLEAN 0
#endif
#if DEBUG_EXPAND
static void debug_print_strings(const char *prefix, char **vv)
{
indent();
fprintf(stderr, "%s:\n", prefix);
while (*vv)
fprintf(stderr, " '%s'\n", *vv++);
}
#else
#define debug_print_strings(prefix, vv) ((void)0)
#endif
/* Leak hunting. Use hush_leaktool.sh for post-processing.
*/
#if LEAK_HUNTING
static void *xxmalloc(int lineno, size_t size)
{
void *ptr = xmalloc((size + 0xff) & ~0xff);
fdprintf(2, "line %d: malloc %p\n", lineno, ptr);
return ptr;
}
static void *xxrealloc(int lineno, void *ptr, size_t size)
{
ptr = xrealloc(ptr, (size + 0xff) & ~0xff);
fdprintf(2, "line %d: realloc %p\n", lineno, ptr);
return ptr;
}
static char *xxstrdup(int lineno, const char *str)
{
char *ptr = xstrdup(str);
fdprintf(2, "line %d: strdup %p\n", lineno, ptr);
return ptr;
}
static void xxfree(void *ptr)
{
fdprintf(2, "free %p\n", ptr);
free(ptr);
}
#define xmalloc(s) xxmalloc(__LINE__, s)
#define xrealloc(p, s) xxrealloc(__LINE__, p, s)
#define xstrdup(s) xxstrdup(__LINE__, s)
#define free(p) xxfree(p)
#endif
/* Syntax and runtime errors. They always abort scripts.
* In interactive use they usually discard unparsed and/or unexecuted commands
* and return to the prompt.
* HUSH_DEBUG >= 2 prints line number in this file where it was detected.
*/
#if HUSH_DEBUG < 2
# define die_if_script(lineno, fmt...) die_if_script(fmt)
# define syntax_error(lineno, msg) syntax_error(msg)
# define syntax_error_at(lineno, msg) syntax_error_at(msg)
# define syntax_error_unterm_ch(lineno, ch) syntax_error_unterm_ch(ch)
# define syntax_error_unterm_str(lineno, s) syntax_error_unterm_str(s)
# define syntax_error_unexpected_ch(lineno, ch) syntax_error_unexpected_ch(ch)
#endif
static void die_if_script(unsigned lineno, const char *fmt, ...)
{
va_list p;
#if HUSH_DEBUG >= 2
bb_error_msg("hush.c:%u", lineno);
#endif
va_start(p, fmt);
bb_verror_msg(fmt, p, NULL);
va_end(p);
if (!G_interactive_fd)
xfunc_die();
}
static void syntax_error(unsigned lineno, const char *msg)
{
if (msg)
die_if_script(lineno, "syntax error: %s", msg);
else
die_if_script(lineno, "syntax error", NULL);
}
static void syntax_error_at(unsigned lineno, const char *msg)
{
die_if_script(lineno, "syntax error at '%s'", msg);
}
/* It so happens that all such cases are totally fatal
* even if shell is interactive: EOF while looking for closing
* delimiter. There is nowhere to read stuff from after that,
* it's EOF! The only choice is to terminate.
*/
static void syntax_error_unterm_ch(unsigned lineno, char ch) NORETURN;
static void syntax_error_unterm_ch(unsigned lineno, char ch)
{
char msg[2];
msg[0] = ch;
msg[1] = '\0';
die_if_script(lineno, "syntax error: unterminated %s", msg);
xfunc_die();
}
static void syntax_error_unterm_str(unsigned lineno, const char *s)
{
die_if_script(lineno, "syntax error: unterminated %s", s);
}
static void syntax_error_unexpected_ch(unsigned lineno, char ch)
{
char msg[2];
msg[0] = ch;
msg[1] = '\0';
die_if_script(lineno, "syntax error: unexpected %s", msg);
}
#if HUSH_DEBUG < 2
# undef die_if_script
# undef syntax_error
# undef syntax_error_at
# undef syntax_error_unterm_ch
# undef syntax_error_unterm_str
# undef syntax_error_unexpected_ch
#else
# define die_if_script(fmt...) die_if_script(__LINE__, fmt)
# define syntax_error(msg) syntax_error(__LINE__, msg)
# define syntax_error_at(msg) syntax_error_at(__LINE__, msg)
# define syntax_error_unterm_ch(ch) syntax_error_unterm_ch(__LINE__, ch)
# define syntax_error_unterm_str(s) syntax_error_unterm_str(__LINE__, s)
# define syntax_error_unexpected_ch(ch) syntax_error_unexpected_ch(__LINE__, ch)
#endif
/* Utility functions
*/
static int glob_needed(const char *s)
{
while (*s) {
if (*s == '\\')
s++;
if (*s == '*' || *s == '[' || *s == '?')
return 1;
s++;
}
return 0;
}
static int is_well_formed_var_name(const char *s, char terminator)
{
if (!s || !(isalpha(*s) || *s == '_'))
return 0;
s++;
while (isalnum(*s) || *s == '_')
s++;
return *s == terminator;
}
/* Replace each \x with x in place, return ptr past NUL. */
static char *unbackslash(char *src)
{
char *dst = src;
while (1) {
if (*src == '\\')
src++;
if ((*dst++ = *src++) == '\0')
break;
}
return dst;
}
static char **add_strings_to_strings(char **strings, char **add, int need_to_dup)
{
int i;
unsigned count1;
unsigned count2;
char **v;
v = strings;
count1 = 0;
if (v) {
while (*v) {
count1++;
v++;
}
}
count2 = 0;
v = add;
while (*v) {
count2++;
v++;
}
v = xrealloc(strings, (count1 + count2 + 1) * sizeof(char*));
v[count1 + count2] = NULL;
i = count2;
while (--i >= 0)
v[count1 + i] = (need_to_dup ? xstrdup(add[i]) : add[i]);
return v;
}
#if LEAK_HUNTING
static char **xx_add_strings_to_strings(int lineno, char **strings, char **add, int need_to_dup)
{
char **ptr = add_strings_to_strings(strings, add, need_to_dup);
fdprintf(2, "line %d: add_strings_to_strings %p\n", lineno, ptr);
return ptr;
}
#define add_strings_to_strings(strings, add, need_to_dup) \
xx_add_strings_to_strings(__LINE__, strings, add, need_to_dup)
#endif
static char **add_string_to_strings(char **strings, char *add)
{
char *v[2];
v[0] = add;
v[1] = NULL;
return add_strings_to_strings(strings, v, /*dup:*/ 0);
}
#if LEAK_HUNTING
static char **xx_add_string_to_strings(int lineno, char **strings, char *add)
{
char **ptr = add_string_to_strings(strings, add);
fdprintf(2, "line %d: add_string_to_strings %p\n", lineno, ptr);
return ptr;
}
#define add_string_to_strings(strings, add) \
xx_add_string_to_strings(__LINE__, strings, add)
#endif
static void putenv_all(char **strings)
{
if (!strings)
return;
while (*strings) {
debug_printf_env("putenv '%s'\n", *strings);
putenv(*strings++);
}
}
static char **putenv_all_and_save_old(char **strings)
{
char **old = NULL;
char **s = strings;
if (!strings)
return old;
while (*strings) {
char *v, *eq;
eq = strchr(*strings, '=');
if (eq) {
*eq = '\0';
v = getenv(*strings);
*eq = '=';
if (v) {
/* v points to VAL in VAR=VAL, go back to VAR */
v -= (eq - *strings) + 1;
old = add_string_to_strings(old, v);
}
}
strings++;
}
putenv_all(s);
return old;
}
static void free_strings_and_unsetenv(char **strings, int unset)
{
char **v;
if (!strings)
return;
v = strings;
while (*v) {
if (unset) {
debug_printf_env("unsetenv '%s'\n", *v);
bb_unsetenv(*v);
}
free(*v++);
}
free(strings);
}
static void free_strings(char **strings)
{
free_strings_and_unsetenv(strings, 0);
}
/* Basic theory of signal handling in shell
* ========================================
* This does not describe what hush does, rather, it is current understanding
* what it _should_ do. If it doesn't, it's a bug.
* http://www.opengroup.org/onlinepubs/9699919799/utilities/V3_chap02.html#trap
*
* Signals are handled only after each pipe ("cmd | cmd | cmd" thing)
* is finished or backgrounded. It is the same in interactive and
* non-interactive shells, and is the same regardless of whether
* a user trap handler is installed or a shell special one is in effect.
* ^C or ^Z from keyboard seem to execute "at once" because it usually
* backgrounds (i.e. stops) or kills all members of currently running
* pipe.
*
* Wait builtin in interruptible by signals for which user trap is set
* or by SIGINT in interactive shell.
*
* Trap handlers will execute even within trap handlers. (right?)
*
* User trap handlers are forgotten when subshell ("(cmd)") is entered.
*
* If job control is off, backgrounded commands ("cmd &")
* have SIGINT, SIGQUIT set to SIG_IGN.
*
* Commands run in command substitution ("`cmd`")
* have SIGTTIN, SIGTTOU, SIGTSTP set to SIG_IGN.
*
* Ordinary commands have signals set to SIG_IGN/DFL set as inherited
* by the shell from its parent.
*
* Siganls which differ from SIG_DFL action
* (note: child (i.e., [v]forked) shell is not an interactive shell):
*
* SIGQUIT: ignore
* SIGTERM (interactive): ignore
* SIGHUP (interactive):
* send SIGCONT to stopped jobs, send SIGHUP to all jobs and exit
* SIGTTIN, SIGTTOU, SIGTSTP (if job control is on): ignore
* Note that ^Z is handled not by trapping SIGTSTP, but by seeing
* that all pipe members are stopped. Try this in bash:
* while :; do :; done - ^Z does not background it
* (while :; do :; done) - ^Z backgrounds it
* SIGINT (interactive): wait for last pipe, ignore the rest
* of the command line, show prompt. NB: ^C does not send SIGINT
* to interactive shell while shell is waiting for a pipe,
* since shell is bg'ed (is not in foreground process group).
* Example 1: this waits 5 sec, but does not execute ls:
* "echo $$; sleep 5; ls -l" + "kill -INT <pid>"
* Example 2: this does not wait and does not execute ls:
* "echo $$; sleep 5 & wait; ls -l" + "kill -INT <pid>"
* Example 3: this does not wait 5 sec, but executes ls:
* "sleep 5; ls -l" + press ^C
*
* (What happens to signals which are IGN on shell start?)
* (What happens with signal mask on shell start?)
*
* Implementation in hush
* ======================
* We use in-kernel pending signal mask to determine which signals were sent.
* We block all signals which we don't want to take action immediately,
* i.e. we block all signals which need to have special handling as described
* above, and all signals which have traps set.
* After each pipe execution, we extract any pending signals via sigtimedwait()
* and act on them.
*
* unsigned non_DFL_mask: a mask of such "special" signals
* sigset_t blocked_set: current blocked signal set
*
* "trap - SIGxxx":
* clear bit in blocked_set unless it is also in non_DFL_mask
* "trap 'cmd' SIGxxx":
* set bit in blocked_set (even if 'cmd' is '')
* after [v]fork, if we plan to be a shell:
* nothing for {} child shell (say, "true | { true; true; } | true")
* unset all traps if () shell.
* after [v]fork, if we plan to exec:
* POSIX says pending signal mask is cleared in child - no need to clear it.
* Restore blocked signal set to one inherited by shell just prior to exec.
*
* Note: as a result, we do not use signal handlers much. The only uses
* are to count SIGCHLDs [disabled - bug somewhere, + bloat]
* and to restore tty pgrp on signal-induced exit.
*/
//static void SIGCHLD_handler(int sig UNUSED_PARAM)
//{
// G.count_SIGCHLD++;
//}
static int check_and_run_traps(int sig)
{
static const struct timespec zero_timespec = { 0, 0 };
smalluint save_rcode;
int last_sig = 0;
if (sig)
goto jump_in;
while (1) {
sig = sigtimedwait(&G.blocked_set, NULL, &zero_timespec);
if (sig <= 0)
break;
jump_in:
last_sig = sig;
if (G.traps && G.traps[sig]) {
if (G.traps[sig][0]) {
/* We have user-defined handler */
char *argv[] = { NULL, xstrdup(G.traps[sig]), NULL };
save_rcode = G.last_exitcode;
builtin_eval(argv);
free(argv[1]);
G.last_exitcode = save_rcode;
} /* else: "" trap, ignoring signal */
continue;
}
/* not a trap: special action */
switch (sig) {
// case SIGCHLD:
// G.count_SIGCHLD++;
// break;
case SIGINT:
bb_putchar('\n');
G.flag_SIGINT = 1;
break;
//TODO
// case SIGHUP: ...
// break;
default: /* ignored: */
/* SIGTERM, SIGQUIT, SIGTTIN, SIGTTOU, SIGTSTP */
break;
}
}
return last_sig;
}
#if ENABLE_HUSH_JOB
/* After [v]fork, in child: do not restore tty pgrp on xfunc death */
#define disable_restore_tty_pgrp_on_exit() (die_sleep = 0)
/* After [v]fork, in parent: restore tty pgrp on xfunc death */
#define enable_restore_tty_pgrp_on_exit() (die_sleep = -1)
/* Restores tty foreground process group, and exits.
* May be called as signal handler for fatal signal
* (will faithfully resend signal to itself, producing correct exit state)
* or called directly with -EXITCODE.
* We also call it if xfunc is exiting. */
static void sigexit(int sig) NORETURN;
static void sigexit(int sig)
{
/* Disable all signals: job control, SIGPIPE, etc. */
sigprocmask_allsigs(SIG_BLOCK);
/* Careful: we can end up here after [v]fork. Do not restore
* tty pgrp then, only top-level shell process does that */
if (G_interactive_fd && getpid() == G.root_pid)
tcsetpgrp(G_interactive_fd, G.saved_tty_pgrp);
/* Not a signal, just exit */
if (sig <= 0)
_exit(- sig);
kill_myself_with_sig(sig); /* does not return */
}
#else
#define disable_restore_tty_pgrp_on_exit() ((void)0)
#define enable_restore_tty_pgrp_on_exit() ((void)0)
#endif
/* Restores tty foreground process group, and exits. */
static void hush_exit(int exitcode) NORETURN;
static void hush_exit(int exitcode)
{
if (G.exiting <= 0 && G.traps && G.traps[0] && G.traps[0][0]) {
/* Prevent recursion:
* trap "echo Hi; exit" EXIT; exit
*/
char *argv[] = { NULL, G.traps[0], NULL };
G.traps[0] = NULL;
G.exiting = 1;
builtin_eval(argv);
free(argv[1]);
}
#if ENABLE_HUSH_JOB
fflush(NULL); /* flush all streams */
sigexit(- (exitcode & 0xff));
#else
exit(exitcode);
#endif
}
static const char *set_cwd(void)
{
/* xrealloc_getcwd_or_warn(arg) calls free(arg),
* we must not try to free(bb_msg_unknown) */
if (G.cwd == bb_msg_unknown)
G.cwd = NULL;
G.cwd = xrealloc_getcwd_or_warn((char *)G.cwd);
if (!G.cwd)
G.cwd = bb_msg_unknown;
return G.cwd;
}
/* Get/check local shell variables */
static struct variable *get_local_var(const char *name)
{
struct variable *cur;
int len;
if (!name)
return NULL;
len = strlen(name);
for (cur = G.top_var; cur; cur = cur->next) {
if (strncmp(cur->varstr, name, len) == 0 && cur->varstr[len] == '=')
return cur;
}
return NULL;
}
static const char *get_local_var_value(const char *src)
{
struct variable *var = get_local_var(src);
if (var)
return strchr(var->varstr, '=') + 1;
return NULL;
}
/* str holds "NAME=VAL" and is expected to be malloced.
* We take ownership of it.
* flg_export:
* 0: do not export
* 1: export
* -1: if NAME is set, leave export status alone
* if NAME is not set, do not export
* flg_read_only is set only when we handle -R var=val
*/
#if BB_MMU
#define set_local_var(str, flg_export, flg_read_only) \
set_local_var(str, flg_export)
#endif
static int set_local_var(char *str, int flg_export, int flg_read_only)
{
struct variable *cur;
char *value;
int name_len;
value = strchr(str, '=');
if (!value) { /* not expected to ever happen? */
free(str);
return -1;
}
name_len = value - str + 1; /* including '=' */
cur = G.top_var; /* cannot be NULL (we have HUSH_VERSION and it's RO) */
while (1) {
if (strncmp(cur->varstr, str, name_len) != 0) {
if (!cur->next) {
/* Bail out. Note that now cur points
* to last var in linked list */
break;
}
cur = cur->next;
continue;
}
/* We found an existing var with this name */
*value = '\0';
if (cur->flg_read_only) {
#if !BB_MMU
if (!flg_read_only)
#endif
bb_error_msg("%s: readonly variable", str);
free(str);
return -1;
}
debug_printf_env("%s: unsetenv '%s'\n", __func__, str);
unsetenv(str); /* just in case */
*value = '=';
if (strcmp(cur->varstr, str) == 0) {
free_and_exp:
free(str);
goto exp;
}
if (cur->max_len >= strlen(str)) {
/* This one is from startup env, reuse space */
strcpy(cur->varstr, str);
goto free_and_exp;
}
/* max_len == 0 signifies "malloced" var, which we can
* (and has to) free */
if (!cur->max_len)
free(cur->varstr);
cur->max_len = 0;
goto set_str_and_exp;
}
/* Not found - create next variable struct */
cur->next = xzalloc(sizeof(*cur));
cur = cur->next;
set_str_and_exp:
cur->varstr = str;
#if !BB_MMU
cur->flg_read_only = flg_read_only;
#endif
exp:
if (flg_export == 1)
cur->flg_export = 1;
if (cur->flg_export) {
debug_printf_env("%s: putenv '%s'\n", __func__, cur->varstr);
return putenv(cur->varstr);
}
return 0;
}
static int unset_local_var(const char *name)
{
struct variable *cur;
struct variable *prev = prev; /* for gcc */
int name_len;
if (!name)
return EXIT_SUCCESS;
name_len = strlen(name);
cur = G.top_var;
while (cur) {
if (strncmp(cur->varstr, name, name_len) == 0 && cur->varstr[name_len] == '=') {
if (cur->flg_read_only) {
bb_error_msg("%s: readonly variable", name);
return EXIT_FAILURE;
}
/* prev is ok to use here because 1st variable, HUSH_VERSION,
* is ro, and we cannot reach this code on the 1st pass */
prev->next = cur->next;
debug_printf_env("%s: unsetenv '%s'\n", __func__, cur->varstr);
bb_unsetenv(cur->varstr);
if (!cur->max_len)
free(cur->varstr);
free(cur);
return EXIT_SUCCESS;
}
prev = cur;
cur = cur->next;
}
return EXIT_SUCCESS;
}
#if ENABLE_SH_MATH_SUPPORT
#define is_name(c) ((c) == '_' || isalpha((unsigned char)(c)))
#define is_in_name(c) ((c) == '_' || isalnum((unsigned char)(c)))
static char *endofname(const char *name)
{
char *p;
p = (char *) name;
if (!is_name(*p))
return p;
while (*++p) {
if (!is_in_name(*p))
break;
}
return p;
}
static void arith_set_local_var(const char *name, const char *val, int flags)
{
/* arith code doesnt malloc space, so do it for it */
char *var = xasprintf("%s=%s", name, val);
set_local_var(var, flags, 0);
}
#endif
/*
* in_str support
*/
static int static_get(struct in_str *i)
{
int ch = *i->p++;
if (ch != '\0')
return ch;
i->p--;
return EOF;
}
static int static_peek(struct in_str *i)
{
return *i->p;
}
#if ENABLE_HUSH_INTERACTIVE
static void cmdedit_set_initial_prompt(void)
{
if (ENABLE_FEATURE_EDITING_FANCY_PROMPT) {
G.PS1 = getenv("PS1");
if (G.PS1 == NULL)
G.PS1 = "\\w \\$ ";
} else
G.PS1 = NULL;
}
static const char* setup_prompt_string(int promptmode)
{
const char *prompt_str;
debug_printf("setup_prompt_string %d ", promptmode);
if (!ENABLE_FEATURE_EDITING_FANCY_PROMPT) {
/* Set up the prompt */
if (promptmode == 0) { /* PS1 */
free((char*)G.PS1);
G.PS1 = xasprintf("%s %c ", G.cwd, (geteuid() != 0) ? '$' : '#');
prompt_str = G.PS1;
} else
prompt_str = G.PS2;
} else
prompt_str = (promptmode == 0) ? G.PS1 : G.PS2;
debug_printf("result '%s'\n", prompt_str);
return prompt_str;
}
static void get_user_input(struct in_str *i)
{
int r;
const char *prompt_str;
prompt_str = setup_prompt_string(i->promptmode);
#if ENABLE_FEATURE_EDITING
/* Enable command line editing only while a command line
* is actually being read */
do {
G.flag_SIGINT = 0;
/* buglet: SIGINT will not make new prompt to appear _at once_,
* only after <Enter>. (^C will work) */
r = read_line_input(prompt_str, G.user_input_buf, BUFSIZ-1, G.line_input_state);
/* catch *SIGINT* etc (^C is handled by read_line_input) */
check_and_run_traps(0);
} while (r == 0 || G.flag_SIGINT); /* repeat if ^C or SIGINT */
i->eof_flag = (r < 0);
if (i->eof_flag) { /* EOF/error detected */
G.user_input_buf[0] = EOF; /* yes, it will be truncated, it's ok */
G.user_input_buf[1] = '\0';
}
#else
do {
G.flag_SIGINT = 0;
fputs(prompt_str, stdout);
fflush(stdout);
G.user_input_buf[0] = r = fgetc(i->file);
/*G.user_input_buf[1] = '\0'; - already is and never changed */
//do we need check_and_run_traps(0)? (maybe only if stdin)
} while (G.flag_SIGINT);
i->eof_flag = (r == EOF);
#endif
i->p = G.user_input_buf;
}
#endif /* INTERACTIVE */
/* This is the magic location that prints prompts
* and gets data back from the user */
static int file_get(struct in_str *i)
{
int ch;
/* If there is data waiting, eat it up */
if (i->p && *i->p) {
#if ENABLE_HUSH_INTERACTIVE
take_cached:
#endif
ch = *i->p++;
if (i->eof_flag && !*i->p)
ch = EOF;
/* note: ch is never NUL */
} else {
/* need to double check i->file because we might be doing something
* more complicated by now, like sourcing or substituting. */
#if ENABLE_HUSH_INTERACTIVE
if (G_interactive_fd && i->promptme && i->file == stdin) {
do {
get_user_input(i);
} while (!*i->p); /* need non-empty line */
i->promptmode = 1; /* PS2 */
i->promptme = 0;
goto take_cached;
}
#endif
do ch = fgetc(i->file); while (ch == '\0');
}
debug_printf("file_get: got '%c' %d\n", ch, ch);
#if ENABLE_HUSH_INTERACTIVE
if (ch == '\n')
i->promptme = 1;
#endif
return ch;
}
/* All callers guarantee this routine will never
* be used right after a newline, so prompting is not needed.
*/
static int file_peek(struct in_str *i)
{
int ch;
if (i->p && *i->p) {
if (i->eof_flag && !i->p[1])
return EOF;
return *i->p;
/* note: ch is never NUL */
}
do ch = fgetc(i->file); while (ch == '\0');
i->eof_flag = (ch == EOF);
i->peek_buf[0] = ch;
i->peek_buf[1] = '\0';
i->p = i->peek_buf;
debug_printf("file_peek: got '%c' %d\n", ch, ch);
return ch;
}
static void setup_file_in_str(struct in_str *i, FILE *f)
{
i->peek = file_peek;
i->get = file_get;
#if ENABLE_HUSH_INTERACTIVE
i->promptme = 1;
i->promptmode = 0; /* PS1 */
#endif
i->file = f;
i->p = NULL;
}
static void setup_string_in_str(struct in_str *i, const char *s)
{
i->peek = static_peek;
i->get = static_get;
#if ENABLE_HUSH_INTERACTIVE
i->promptme = 1;
i->promptmode = 0; /* PS1 */
#endif
i->p = s;
i->eof_flag = 0;
}
/*
* o_string support
*/
#define B_CHUNK (32 * sizeof(char*))
static void o_reset_to_empty_unquoted(o_string *o)
{
o->length = 0;
o->o_quoted = 0;
if (o->data)
o->data[0] = '\0';
}
static void o_free(o_string *o)
{
free(o->data);
memset(o, 0, sizeof(*o));
}
static ALWAYS_INLINE void o_free_unsafe(o_string *o)
{
free(o->data);
}
static void o_grow_by(o_string *o, int len)
{
if (o->length + len > o->maxlen) {
o->maxlen += (2*len > B_CHUNK ? 2*len : B_CHUNK);
o->data = xrealloc(o->data, 1 + o->maxlen);
}
}
static void o_addchr(o_string *o, int ch)
{
debug_printf("o_addchr: '%c' o->length=%d o=%p\n", ch, o->length, o);
o_grow_by(o, 1);
o->data[o->length] = ch;
o->length++;
o->data[o->length] = '\0';
}
static void o_addblock(o_string *o, const char *str, int len)
{
o_grow_by(o, len);
memcpy(&o->data[o->length], str, len);
o->length += len;
o->data[o->length] = '\0';
}
#if !BB_MMU
static void o_addstr(o_string *o, const char *str)
{
o_addblock(o, str, strlen(str));
}
static void nommu_addchr(o_string *o, int ch)
{
if (o)
o_addchr(o, ch);
}
#else
#define nommu_addchr(o, str) ((void)0)
#endif
static void o_addstr_with_NUL(o_string *o, const char *str)
{
o_addblock(o, str, strlen(str) + 1);
}
static void o_addblock_duplicate_backslash(o_string *o, const char *str, int len)
{
while (len) {
o_addchr(o, *str);
if (*str++ == '\\'
&& (*str != '*' && *str != '?' && *str != '[')
) {
o_addchr(o, '\\');
}
len--;
}
}
/* My analysis of quoting semantics tells me that state information
* is associated with a destination, not a source.
*/
static void o_addqchr(o_string *o, int ch)
{
int sz = 1;
char *found = strchr("*?[\\", ch);
if (found)
sz++;
o_grow_by(o, sz);
if (found) {
o->data[o->length] = '\\';
o->length++;
}
o->data[o->length] = ch;
o->length++;
o->data[o->length] = '\0';
}
static void o_addQchr(o_string *o, int ch)
{
int sz = 1;
if (o->o_escape && strchr("*?[\\", ch)) {
sz++;
o->data[o->length] = '\\';
o->length++;
}
o_grow_by(o, sz);
o->data[o->length] = ch;
o->length++;
o->data[o->length] = '\0';
}
static void o_addQstr(o_string *o, const char *str, int len)
{
if (!o->o_escape) {
o_addblock(o, str, len);
return;
}
while (len) {
char ch;
int sz;
int ordinary_cnt = strcspn(str, "*?[\\");
if (ordinary_cnt > len) /* paranoia */
ordinary_cnt = len;
o_addblock(o, str, ordinary_cnt);
if (ordinary_cnt == len)
return;
str += ordinary_cnt;
len -= ordinary_cnt + 1; /* we are processing + 1 char below */
ch = *str++;
sz = 1;
if (ch) { /* it is necessarily one of "*?[\\" */
sz++;
o->data[o->length] = '\\';
o->length++;
}
o_grow_by(o, sz);
o->data[o->length] = ch;
o->length++;
o->data[o->length] = '\0';
}
}
/* A special kind of o_string for $VAR and `cmd` expansion.
* It contains char* list[] at the beginning, which is grown in 16 element
* increments. Actual string data starts at the next multiple of 16 * (char*).
* list[i] contains an INDEX (int!) into this string data.
* It means that if list[] needs to grow, data needs to be moved higher up
* but list[i]'s need not be modified.
* NB: remembering how many list[i]'s you have there is crucial.
* o_finalize_list() operation post-processes this structure - calculates
* and stores actual char* ptrs in list[]. Oh, it NULL terminates it as well.
*/
#if DEBUG_EXPAND || DEBUG_GLOB
static void debug_print_list(const char *prefix, o_string *o, int n)
{
char **list = (char**)o->data;
int string_start = ((n + 0xf) & ~0xf) * sizeof(list[0]);
int i = 0;
indent();
fprintf(stderr, "%s: list:%p n:%d string_start:%d length:%d maxlen:%d\n",
prefix, list, n, string_start, o->length, o->maxlen);
while (i < n) {
indent();
fprintf(stderr, " list[%d]=%d '%s' %p\n", i, (int)list[i],
o->data + (int)list[i] + string_start,
o->data + (int)list[i] + string_start);
i++;
}
if (n) {
const char *p = o->data + (int)list[n - 1] + string_start;
indent();
fprintf(stderr, " total_sz:%ld\n", (long)((p + strlen(p) + 1) - o->data));
}
}
#else
#define debug_print_list(prefix, o, n) ((void)0)
#endif
/* n = o_save_ptr_helper(str, n) "starts new string" by storing an index value
* in list[n] so that it points past last stored byte so far.
* It returns n+1. */
static int o_save_ptr_helper(o_string *o, int n)
{
char **list = (char**)o->data;
int string_start;
int string_len;
if (!o->has_empty_slot) {
string_start = ((n + 0xf) & ~0xf) * sizeof(list[0]);
string_len = o->length - string_start;
if (!(n & 0xf)) { /* 0, 0x10, 0x20...? */
debug_printf_list("list[%d]=%d string_start=%d (growing)\n", n, string_len, string_start);
/* list[n] points to string_start, make space for 16 more pointers */
o->maxlen += 0x10 * sizeof(list[0]);
o->data = xrealloc(o->data, o->maxlen + 1);
list = (char**)o->data;
memmove(list + n + 0x10, list + n, string_len);
o->length += 0x10 * sizeof(list[0]);
} else {
debug_printf_list("list[%d]=%d string_start=%d\n",
n, string_len, string_start);
}
} else {
/* We have empty slot at list[n], reuse without growth */
string_start = ((n+1 + 0xf) & ~0xf) * sizeof(list[0]); /* NB: n+1! */
string_len = o->length - string_start;
debug_printf_list("list[%d]=%d string_start=%d (empty slot)\n",
n, string_len, string_start);
o->has_empty_slot = 0;
}
list[n] = (char*)(ptrdiff_t)string_len;
return n + 1;
}
/* "What was our last o_save_ptr'ed position (byte offset relative o->data)?" */
static int o_get_last_ptr(o_string *o, int n)
{
char **list = (char**)o->data;
int string_start = ((n + 0xf) & ~0xf) * sizeof(list[0]);
return ((int)(ptrdiff_t)list[n-1]) + string_start;
}
/* o_glob performs globbing on last list[], saving each result
* as a new list[]. */
static int o_glob(o_string *o, int n)
{
glob_t globdata;
int gr;
char *pattern;
debug_printf_glob("start o_glob: n:%d o->data:%p\n", n, o->data);
if (!o->data)
return o_save_ptr_helper(o, n);
pattern = o->data + o_get_last_ptr(o, n);
debug_printf_glob("glob pattern '%s'\n", pattern);
if (!glob_needed(pattern)) {
literal:
o->length = unbackslash(pattern) - o->data;
debug_printf_glob("glob pattern '%s' is literal\n", pattern);
return o_save_ptr_helper(o, n);
}
memset(&globdata, 0, sizeof(globdata));
gr = glob(pattern, 0, NULL, &globdata);
debug_printf_glob("glob('%s'):%d\n", pattern, gr);
if (gr == GLOB_NOSPACE)
bb_error_msg_and_die("out of memory during glob");
if (gr == GLOB_NOMATCH) {
globfree(&globdata);
goto literal;
}
if (gr != 0) { /* GLOB_ABORTED ? */
//TODO: testcase for bad glob pattern behavior
bb_error_msg("glob(3) error %d on '%s'", gr, pattern);
}
if (globdata.gl_pathv && globdata.gl_pathv[0]) {
char **argv = globdata.gl_pathv;
o->length = pattern - o->data; /* "forget" pattern */
while (1) {
o_addstr_with_NUL(o, *argv);
n = o_save_ptr_helper(o, n);
argv++;
if (!*argv)
break;
}
}
globfree(&globdata);
if (DEBUG_GLOB)
debug_print_list("o_glob returning", o, n);
return n;
}
/* If o->o_glob == 1, glob the string so far remembered.
* Otherwise, just finish current list[] and start new */
static int o_save_ptr(o_string *o, int n)
{
if (o->o_glob) { /* if globbing is requested */
/* If o->has_empty_slot, list[n] was already globbed
* (if it was requested back then when it was filled)
* so don't do that again! */
if (!o->has_empty_slot)
return o_glob(o, n); /* o_save_ptr_helper is inside */
}
return o_save_ptr_helper(o, n);
}
/* "Please convert list[n] to real char* ptrs, and NULL terminate it." */
static char **o_finalize_list(o_string *o, int n)
{
char **list;
int string_start;
n = o_save_ptr(o, n); /* force growth for list[n] if necessary */
if (DEBUG_EXPAND)
debug_print_list("finalized", o, n);
debug_printf_expand("finalized n:%d\n", n);
list = (char**)o->data;
string_start = ((n + 0xf) & ~0xf) * sizeof(list[0]);
list[--n] = NULL;
while (n) {
n--;
list[n] = o->data + (int)(ptrdiff_t)list[n] + string_start;
}
return list;
}
/* Expansion can recurse */
#if ENABLE_HUSH_TICK
static int process_command_subs(o_string *dest, const char *s);
#endif
static char *expand_string_to_string(const char *str);
#if BB_MMU
#define parse_stream_dquoted(as_string, dest, input, dquote_end) \
parse_stream_dquoted(dest, input, dquote_end)
#endif
static int parse_stream_dquoted(o_string *as_string,
o_string *dest,
struct in_str *input,
int dquote_end);
/* expand_strvec_to_strvec() takes a list of strings, expands
* all variable references within and returns a pointer to
* a list of expanded strings, possibly with larger number
* of strings. (Think VAR="a b"; echo $VAR).
* This new list is allocated as a single malloc block.
* NULL-terminated list of char* pointers is at the beginning of it,
* followed by strings themself.
* Caller can deallocate entire list by single free(list). */
/* Store given string, finalizing the word and starting new one whenever
* we encounter IFS char(s). This is used for expanding variable values.
* End-of-string does NOT finalize word: think about 'echo -$VAR-' */
static int expand_on_ifs(o_string *output, int n, const char *str)
{
while (1) {
int word_len = strcspn(str, G.ifs);
if (word_len) {
if (output->o_escape || !output->o_glob)
o_addQstr(output, str, word_len);
else /* protect backslashes against globbing up :) */
o_addblock_duplicate_backslash(output, str, word_len);
str += word_len;
}
if (!*str) /* EOL - do not finalize word */
break;
o_addchr(output, '\0');
debug_print_list("expand_on_ifs", output, n);
n = o_save_ptr(output, n);
str += strspn(str, G.ifs); /* skip ifs chars */
}
debug_print_list("expand_on_ifs[1]", output, n);
return n;
}
/* Helper to expand $((...)) and heredoc body. These act as if
* they are in double quotes, with the exception that they are not :).
* Just the rules are similar: "expand only $var and `cmd`"
*
* Returns malloced string.
* As an optimization, we return NULL if expansion is not needed.
*/
static char *expand_pseudo_dquoted(const char *str)
{
char *exp_str;
struct in_str input;
o_string dest = NULL_O_STRING;
if (strchr(str, '$') == NULL
#if ENABLE_HUSH_TICK
&& strchr(str, '`') == NULL
#endif
) {
return NULL;
}
/* We need to expand. Example:
* echo $(($a + `echo 1`)) $((1 + $((2)) ))
*/
setup_string_in_str(&input, str);
parse_stream_dquoted(NULL, &dest, &input, EOF);
//bb_error_msg("'%s' -> '%s'", str, dest.data);
exp_str = expand_string_to_string(dest.data);
//bb_error_msg("'%s' -> '%s'", dest.data, exp_str);
o_free_unsafe(&dest);
return exp_str;
}
/* Expand all variable references in given string, adding words to list[]
* at n, n+1,... positions. Return updated n (so that list[n] is next one
* to be filled). This routine is extremely tricky: has to deal with
* variables/parameters with whitespace, $* and $@, and constructs like
* 'echo -$*-'. If you play here, you must run testsuite afterwards! */
static int expand_vars_to_list(o_string *output, int n, char *arg, char or_mask)
{
/* or_mask is either 0 (normal case) or 0x80
* (expansion of right-hand side of assignment == 1-element expand.
* It will also do no globbing, and thus we must not backslash-quote!) */
char first_ch, ored_ch;
int i;
const char *val;
char *dyn_val, *p;
dyn_val = NULL;
ored_ch = 0;
debug_printf_expand("expand_vars_to_list: arg '%s'\n", arg);
debug_print_list("expand_vars_to_list", output, n);
n = o_save_ptr(output, n);
debug_print_list("expand_vars_to_list[0]", output, n);
while ((p = strchr(arg, SPECIAL_VAR_SYMBOL)) != NULL) {
#if ENABLE_HUSH_TICK
o_string subst_result = NULL_O_STRING;
#endif
#if ENABLE_SH_MATH_SUPPORT
char arith_buf[sizeof(arith_t)*3 + 2];
#endif
o_addblock(output, arg, p - arg);
debug_print_list("expand_vars_to_list[1]", output, n);
arg = ++p;
p = strchr(p, SPECIAL_VAR_SYMBOL);
first_ch = arg[0] | or_mask; /* forced to "quoted" if or_mask = 0x80 */
/* "$@" is special. Even if quoted, it can still
* expand to nothing (not even an empty string) */
if ((first_ch & 0x7f) != '@')
ored_ch |= first_ch;
val = NULL;
switch (first_ch & 0x7f) {
/* Highest bit in first_ch indicates that var is double-quoted */
case '$': /* pid */
val = utoa(G.root_pid);
break;
case '!': /* bg pid */
val = G.last_bg_pid ? utoa(G.last_bg_pid) : (char*)"";
break;
case '?': /* exitcode */
val = utoa(G.last_exitcode);
break;
case '#': /* argc */
if (arg[1] != SPECIAL_VAR_SYMBOL)
/* actually, it's a ${#var} */
goto case_default;
val = utoa(G.global_argc ? G.global_argc-1 : 0);
break;
case '*':
case '@':
i = 1;
if (!G.global_argv[i])
break;
ored_ch |= first_ch; /* do it for "$@" _now_, when we know it's not empty */
if (!(first_ch & 0x80)) { /* unquoted $* or $@ */
smallint sv = output->o_escape;
/* unquoted var's contents should be globbed, so don't escape */
output->o_escape = 0;
while (G.global_argv[i]) {
n = expand_on_ifs(output, n, G.global_argv[i]);
debug_printf_expand("expand_vars_to_list: argv %d (last %d)\n", i, G.global_argc - 1);
if (G.global_argv[i++][0] && G.global_argv[i]) {
/* this argv[] is not empty and not last:
* put terminating NUL, start new word */
o_addchr(output, '\0');
debug_print_list("expand_vars_to_list[2]", output, n);
n = o_save_ptr(output, n);
debug_print_list("expand_vars_to_list[3]", output, n);
}
}
output->o_escape = sv;
} else
/* If or_mask is nonzero, we handle assignment 'a=....$@.....'
* and in this case should treat it like '$*' - see 'else...' below */
if (first_ch == ('@'|0x80) && !or_mask) { /* quoted $@ */
while (1) {
o_addQstr(output, G.global_argv[i], strlen(G.global_argv[i]));
if (++i >= G.global_argc)
break;
o_addchr(output, '\0');
debug_print_list("expand_vars_to_list[4]", output, n);
n = o_save_ptr(output, n);
}
} else { /* quoted $*: add as one word */
while (1) {
o_addQstr(output, G.global_argv[i], strlen(G.global_argv[i]));
if (!G.global_argv[++i])
break;
if (G.ifs[0])
o_addchr(output, G.ifs[0]);
}
}
break;
case SPECIAL_VAR_SYMBOL: /* <SPECIAL_VAR_SYMBOL><SPECIAL_VAR_SYMBOL> */
/* "Empty variable", used to make "" etc to not disappear */
arg++;
ored_ch = 0x80;
break;
#if ENABLE_HUSH_TICK
case '`': /* <SPECIAL_VAR_SYMBOL>`cmd<SPECIAL_VAR_SYMBOL> */
*p = '\0';
arg++;
//TODO: can we just stuff it into "output" directly?
debug_printf_subst("SUBST '%s' first_ch %x\n", arg, first_ch);
process_command_subs(&subst_result, arg);
debug_printf_subst("SUBST RES '%s'\n", subst_result.data);
val = subst_result.data;
goto store_val;
#endif
#if ENABLE_SH_MATH_SUPPORT
case '+': { /* <SPECIAL_VAR_SYMBOL>+cmd<SPECIAL_VAR_SYMBOL> */
arith_eval_hooks_t hooks;
arith_t res;
int errcode;
char *exp_str;
arg++; /* skip '+' */
*p = '\0'; /* replace trailing <SPECIAL_VAR_SYMBOL> */
debug_printf_subst("ARITH '%s' first_ch %x\n", arg, first_ch);
exp_str = expand_pseudo_dquoted(arg);
hooks.lookupvar = get_local_var_value;
hooks.setvar = arith_set_local_var;
hooks.endofname = endofname;
res = arith(exp_str ? exp_str : arg, &errcode, &hooks);
free(exp_str);
if (errcode < 0) {
const char *msg = "error in arithmetic";
switch (errcode) {
case -3:
msg = "exponent less than 0";
break;
case -2:
msg = "divide by 0";
break;
case -5:
msg = "expression recursion loop detected";
break;
}
die_if_script(msg);
}
debug_printf_subst("ARITH RES '"arith_t_fmt"'\n", res);
sprintf(arith_buf, arith_t_fmt, res);
val = arith_buf;
break;
}
#endif
default: /* <SPECIAL_VAR_SYMBOL>varname<SPECIAL_VAR_SYMBOL> */
case_default: {
bool exp_len = false;
bool exp_null = false;
char *var = arg;
char exp_save = exp_save; /* for compiler */
char exp_op = exp_op; /* for compiler */
char *exp_word = exp_word; /* for compiler */
size_t exp_off = 0;
*p = '\0';
arg[0] = first_ch & 0x7f;
/* prepare for expansions */
if (var[0] == '#') {
/* handle length expansion ${#var} */
exp_len = true;
++var;
} else {
/* maybe handle parameter expansion */
exp_off = strcspn(var, ":-=+?%#");
if (!var[exp_off])
exp_off = 0;
if (exp_off) {
exp_save = var[exp_off];
exp_null = exp_save == ':';
exp_word = var + exp_off;
if (exp_null)
++exp_word;
exp_op = *exp_word++;
var[exp_off] = '\0';
}
}
/* lookup the variable in question */
if (isdigit(var[0])) {
/* handle_dollar() should have vetted var for us */
i = xatoi_u(var);
if (i < G.global_argc)
val = G.global_argv[i];
/* else val remains NULL: $N with too big N */
} else
val = get_local_var_value(var);
/* handle any expansions */
if (exp_len) {
debug_printf_expand("expand: length of '%s' = ", val);
val = utoa(val ? strlen(val) : 0);
debug_printf_expand("%s\n", val);
} else if (exp_off) {
if (exp_op == '%' || exp_op == '#') {
if (val) {
/* we need to do a pattern match */
bool zero;
char *loc;
scan_t scan = pick_scan(exp_op, *exp_word, &zero);
if (exp_op == *exp_word) /* ## or %% */
++exp_word;
val = dyn_val = xstrdup(val);
loc = scan(dyn_val, exp_word, zero);
if (zero)
val = loc;
else
*loc = '\0';
}
} else {
/* we need to do an expansion */
int exp_test = (!val || (exp_null && !val[0]));
if (exp_op == '+')
exp_test = !exp_test;
debug_printf_expand("expand: op:%c (null:%s) test:%i\n", exp_op,
exp_null ? "true" : "false", exp_test);
if (exp_test) {
if (exp_op == '?') {
//TODO: how interactive bash aborts expansion mid-command?
/* ${var?[error_msg_if_unset]} */
/* ${var:?[error_msg_if_unset_or_null]} */
/* mimic bash message */
die_if_script("%s: %s",
var,
exp_word[0] ? exp_word : "parameter null or not set"
);
} else {
val = exp_word;
}
if (exp_op == '=') {
/* ${var=[word]} or ${var:=[word]} */
if (isdigit(var[0]) || var[0] == '#') {
/* mimic bash message */
die_if_script("$%s: cannot assign in this way", var);
val = NULL;
} else {
char *new_var = xasprintf("%s=%s", var, val);
set_local_var(new_var, -1, 0);
}
}
}
}
var[exp_off] = exp_save;
}
arg[0] = first_ch;
#if ENABLE_HUSH_TICK
store_val:
#endif
if (!(first_ch & 0x80)) { /* unquoted $VAR */
debug_printf_expand("unquoted '%s', output->o_escape:%d\n", val, output->o_escape);
if (val) {
/* unquoted var's contents should be globbed, so don't escape */
smallint sv = output->o_escape;
output->o_escape = 0;
n = expand_on_ifs(output, n, val);
val = NULL;
output->o_escape = sv;
}
} else { /* quoted $VAR, val will be appended below */
debug_printf_expand("quoted '%s', output->o_escape:%d\n", val, output->o_escape);
}
} /* default: */
} /* switch (char after <SPECIAL_VAR_SYMBOL>) */
if (val) {
o_addQstr(output, val, strlen(val));
}
free(dyn_val);
dyn_val = NULL;
/* Do the check to avoid writing to a const string */
if (*p != SPECIAL_VAR_SYMBOL)
*p = SPECIAL_VAR_SYMBOL;
#if ENABLE_HUSH_TICK
o_free(&subst_result);
#endif
arg = ++p;
} /* end of "while (SPECIAL_VAR_SYMBOL is found) ..." */
if (arg[0]) {
debug_print_list("expand_vars_to_list[a]", output, n);
/* this part is literal, and it was already pre-quoted
* if needed (much earlier), do not use o_addQstr here! */
o_addstr_with_NUL(output, arg);
debug_print_list("expand_vars_to_list[b]", output, n);
} else if (output->length == o_get_last_ptr(output, n) /* expansion is empty */
&& !(ored_ch & 0x80) /* and all vars were not quoted. */
) {
n--;
/* allow to reuse list[n] later without re-growth */
output->has_empty_slot = 1;
} else {
o_addchr(output, '\0');
}
return n;
}
static char **expand_variables(char **argv, int or_mask)
{
int n;
char **list;
char **v;
o_string output = NULL_O_STRING;
if (or_mask & 0x100) {
output.o_escape = 1; /* protect against globbing for "$var" */
/* (unquoted $var will temporarily switch it off) */
output.o_glob = 1;
}
n = 0;
v = argv;
while (*v) {
n = expand_vars_to_list(&output, n, *v, (char)or_mask);
v++;
}
debug_print_list("expand_variables", &output, n);
/* output.data (malloced in one block) gets returned in "list" */
list = o_finalize_list(&output, n);
debug_print_strings("expand_variables[1]", list);
return list;
}
static char **expand_strvec_to_strvec(char **argv)
{
return expand_variables(argv, 0x100);
}
/* Used for expansion of right hand of assignments */
/* NB: should NOT do globbing! "export v=/bin/c*; env | grep ^v=" outputs
* "v=/bin/c*" */
static char *expand_string_to_string(const char *str)
{
char *argv[2], **list;
argv[0] = (char*)str;
argv[1] = NULL;
list = expand_variables(argv, 0x80); /* 0x80: make one-element expansion */
if (HUSH_DEBUG)
if (!list[0] || list[1])
bb_error_msg_and_die("BUG in varexp2");
/* actually, just move string 2*sizeof(char*) bytes back */
overlapping_strcpy((char*)list, list[0]);
debug_printf_expand("string_to_string='%s'\n", (char*)list);
return (char*)list;
}
/* Used for "eval" builtin */
static char* expand_strvec_to_string(char **argv)
{
char **list;
list = expand_variables(argv, 0x80);
/* Convert all NULs to spaces */
if (list[0]) {
int n = 1;
while (list[n]) {
if (HUSH_DEBUG)
if (list[n-1] + strlen(list[n-1]) + 1 != list[n])
bb_error_msg_and_die("BUG in varexp3");
list[n][-1] = ' '; /* TODO: or to G.ifs[0]? */
n++;
}
}
overlapping_strcpy((char*)list, list[0]);
debug_printf_expand("strvec_to_string='%s'\n", (char*)list);
return (char*)list;
}
static char **expand_assignments(char **argv, int count)
{
int i;
char **p = NULL;
/* Expand assignments into one string each */
for (i = 0; i < count; i++) {
p = add_string_to_strings(p, expand_string_to_string(argv[i]));
}
return p;
}
#if BB_MMU
/* never called */
void re_execute_shell(char ***to_free, const char *s, char *argv0, char **argv);
static void reset_traps_to_defaults(void)
{
enum {
JOBSIGS = (1 << SIGTTIN) | (1 << SIGTTOU) | (1 << SIGTSTP)
};
unsigned sig;
if (!G.traps && !(G.non_DFL_mask & JOBSIGS))
return;
/* This function is always called in a child shell.
* Child shells are not interactive.
* SIGTTIN/SIGTTOU/SIGTSTP should not have special handling.
* Testcase: (while :; do :; done) + ^Z should background.
*/
G.non_DFL_mask &= ~JOBSIGS;
sigdelset(&G.blocked_set, SIGTTIN);
sigdelset(&G.blocked_set, SIGTTOU);
sigdelset(&G.blocked_set, SIGTSTP);
if (G.traps) for (sig = 0; sig < NSIG; sig++) {
if (!G.traps[sig]) {
continue;
}
free(G.traps[sig]);
G.traps[sig] = NULL;
/* There is no signal for 0 (EXIT) */
if (sig == 0)
continue;
/* there was a trap handler, we are removing it
* (if sig has non-DFL handling,
* we don't need to do anything) */
if (sig < 32 && (G.non_DFL_mask & (1 << sig)))
continue;
sigdelset(&G.blocked_set, sig);
}
sigprocmask(SIG_SETMASK, &G.blocked_set, NULL);
}
#else /* !BB_MMU */
static void re_execute_shell(char ***to_free, const char *s, char *g_argv0, char **g_argv) NORETURN;
static void re_execute_shell(char ***to_free, const char *s, char *g_argv0, char **g_argv)
{
char param_buf[sizeof("-$%x:%x:%x:%x") + sizeof(unsigned) * 4];
char *heredoc_argv[4];
struct variable *cur;
#if ENABLE_HUSH_FUNCTIONS
struct function *funcp;
#endif
char **argv, **pp;
unsigned cnt;
if (!g_argv0) { /* heredoc */
argv = heredoc_argv;
argv[0] = (char *) G.argv0_for_re_execing;
argv[1] = (char *) "-<";
argv[2] = (char *) s;
argv[3] = NULL;
pp = &argv[3]; /* used as pointer to empty environment */
goto do_exec;
}
sprintf(param_buf, "-$%x:%x:%x" USE_HUSH_LOOPS(":%x")
, (unsigned) G.root_pid
, (unsigned) G.last_bg_pid
, (unsigned) G.last_exitcode
USE_HUSH_LOOPS(, G.depth_of_loop)
);
/* 1:hush 2:-$<pid>:<pid>:<exitcode>:<depth> <vars...> <funcs...>
* 3:-c 4:<cmd> 5:<arg0> <argN...> 6:NULL
*/
cnt = 6;
for (cur = G.top_var; cur; cur = cur->next) {
if (!cur->flg_export || cur->flg_read_only)
cnt += 2;
}
#if ENABLE_HUSH_FUNCTIONS
for (funcp = G.top_func; funcp; funcp = funcp->next)
cnt += 3;
#endif
pp = g_argv;
while (*pp++)
cnt++;
*to_free = argv = pp = xzalloc(sizeof(argv[0]) * cnt);
*pp++ = (char *) G.argv0_for_re_execing;
*pp++ = param_buf;
for (cur = G.top_var; cur; cur = cur->next) {
if (cur->varstr == hush_version_str)
continue;
if (cur->flg_read_only) {
*pp++ = (char *) "-R";
*pp++ = cur->varstr;
} else if (!cur->flg_export) {
*pp++ = (char *) "-V";
*pp++ = cur->varstr;
}
}
#if ENABLE_HUSH_FUNCTIONS
for (funcp = G.top_func; funcp; funcp = funcp->next) {
*pp++ = (char *) "-F";
*pp++ = funcp->name;
*pp++ = funcp->body_as_string;
}
#endif
/* We can pass activated traps here. Say, -Tnn:trap_string
*
* However, POSIX says that subshells reset signals with traps
* to SIG_DFL.
* I tested bash-3.2 and it not only does that with true subshells
* of the form ( list ), but with any forked children shells.
* I set trap "echo W" WINCH; and then tried:
*
* { echo 1; sleep 20; echo 2; } &
* while true; do echo 1; sleep 20; echo 2; break; done &
* true | { echo 1; sleep 20; echo 2; } | cat
*
* In all these cases sending SIGWINCH to the child shell
* did not run the trap. If I add trap "echo V" WINCH;
* _inside_ group (just before echo 1), it works.
*
* I conclude it means we don't need to pass active traps here.
* exec syscall below resets them to SIG_DFL for us.
*/
*pp++ = (char *) "-c";
*pp++ = (char *) s;
*pp++ = g_argv0;
while (*g_argv)
*pp++ = *g_argv++;
/* *pp = NULL; - is already there */
pp = environ;
do_exec:
debug_printf_exec("re_execute_shell pid:%d cmd:'%s'\n", getpid(), s);
sigprocmask(SIG_SETMASK, &G.inherited_set, NULL);
execve(bb_busybox_exec_path, argv, pp);
/* Fallback. Useful for init=/bin/hush usage etc */
if (argv[0][0] == '/')
execve(argv[0], argv, pp);
xfunc_error_retval = 127;
bb_error_msg_and_die("can't re-execute the shell");
}
#endif /* !BB_MMU */
static void setup_heredoc(struct redir_struct *redir)
{
struct fd_pair pair;
pid_t pid;
int len, written;
/* the _body_ of heredoc (misleading field name) */
const char *heredoc = redir->rd_filename;
char *expanded;
#if !BB_MMU
char **to_free;
#endif
expanded = NULL;
if (!(redir->rd_dup & HEREDOC_QUOTED)) {
expanded = expand_pseudo_dquoted(heredoc);
if (expanded)
heredoc = expanded;
}
len = strlen(heredoc);
close(redir->rd_fd); /* often saves dup2+close in xmove_fd */
xpiped_pair(pair);
xmove_fd(pair.rd, redir->rd_fd);
/* Try writing without forking. Newer kernels have
* dynamically growing pipes. Must use non-blocking write! */
ndelay_on(pair.wr);
while (1) {
written = write(pair.wr, heredoc, len);
if (written <= 0)
break;
len -= written;
if (len == 0) {
close(pair.wr);
free(expanded);
return;
}
heredoc += written;
}
ndelay_off(pair.wr);
/* Okay, pipe buffer was not big enough */
/* Note: we must not create a stray child (bastard? :)
* for the unsuspecting parent process. Child creates a grandchild
* and exits before parent execs the process which consumes heredoc
* (that exec happens after we return from this function) */
#if !BB_MMU
to_free = NULL;
#endif
pid = vfork();
if (pid < 0)
bb_perror_msg_and_die("vfork");
if (pid == 0) {
/* child */
disable_restore_tty_pgrp_on_exit();
pid = BB_MMU ? fork() : vfork();
if (pid < 0)
bb_perror_msg_and_die(BB_MMU ? "fork" : "vfork");
if (pid != 0)
_exit(0);
/* grandchild */
close(redir->rd_fd); /* read side of the pipe */
#if BB_MMU
full_write(pair.wr, heredoc, len); /* may loop or block */
_exit(0);
#else
/* Delegate blocking writes to another process */
xmove_fd(pair.wr, STDOUT_FILENO);
re_execute_shell(&to_free, heredoc, NULL, NULL);
#endif
}
/* parent */
enable_restore_tty_pgrp_on_exit();
#if !BB_MMU
free(to_free);
#endif
close(pair.wr);
free(expanded);
wait(NULL); /* wait till child has died */
}
/* squirrel != NULL means we squirrel away copies of stdin, stdout,
* and stderr if they are redirected. */
static int setup_redirects(struct command *prog, int squirrel[])
{
int openfd, mode;
struct redir_struct *redir;
for (redir = prog->redirects; redir; redir = redir->next) {
if (redir->rd_type == REDIRECT_HEREDOC2) {
/* rd_fd<<HERE case */
if (squirrel && redir->rd_fd < 3) {
squirrel[redir->rd_fd] = dup(redir->rd_fd);
}
/* for REDIRECT_HEREDOC2, rd_filename holds _contents_
* of the heredoc */
debug_printf_parse("set heredoc '%s'\n",
redir->rd_filename);
setup_heredoc(redir);
continue;
}
if (redir->rd_dup == REDIRFD_TO_FILE) {
/* rd_fd<*>file case (<*> is <,>,>>,<>) */
char *p;
if (redir->rd_filename == NULL) {
/* Something went wrong in the parse.
* Pretend it didn't happen */
bb_error_msg("bug in redirect parse");
continue;
}
mode = redir_table[redir->rd_type].mode;
p = expand_string_to_string(redir->rd_filename);
openfd = open_or_warn(p, mode);
free(p);
if (openfd < 0) {
/* this could get lost if stderr has been redirected, but
* bash and ash both lose it as well (though zsh doesn't!) */
//what the above comment tries to say?
return 1;
}
} else {
/* rd_fd<*>rd_dup or rd_fd<*>- cases */
openfd = redir->rd_dup;
}
if (openfd != redir->rd_fd) {
if (squirrel && redir->rd_fd < 3) {
squirrel[redir->rd_fd] = dup(redir->rd_fd);
}
if (openfd == REDIRFD_CLOSE) {
/* "n>-" means "close me" */
close(redir->rd_fd);
} else {
xdup2(openfd, redir->rd_fd);
if (redir->rd_dup == REDIRFD_TO_FILE)
close(openfd);
}
}
}
return 0;
}
static void restore_redirects(int squirrel[])
{
int i, fd;
for (i = 0; i < 3; i++) {
fd = squirrel[i];
if (fd != -1) {
/* We simply die on error */
xmove_fd(fd, i);
}
}
}
static void free_pipe_list(struct pipe *head);
/* Return code is the exit status of the pipe */
static void free_pipe(struct pipe *pi)
{
char **p;
struct command *command;
struct redir_struct *r, *rnext;
int a, i;
if (pi->stopped_cmds > 0) /* why? */
return;
debug_printf_clean("run pipe: (pid %d)\n", getpid());
for (i = 0; i < pi->num_cmds; i++) {
command = &pi->cmds[i];
debug_printf_clean(" command %d:\n", i);
if (command->argv) {
for (a = 0, p = command->argv; *p; a++, p++) {
debug_printf_clean(" argv[%d] = %s\n", a, *p);
}
free_strings(command->argv);
command->argv = NULL;
}
/* not "else if": on syntax error, we may have both! */
if (command->group) {
debug_printf_clean(" begin group (grp_type:%d)\n",
command->grp_type);
free_pipe_list(command->group);
debug_printf_clean(" end group\n");
command->group = NULL;
}
/* else is crucial here.
* If group != NULL, child_func is meaningless */
#if ENABLE_HUSH_FUNCTIONS
else if (command->child_func) {
debug_printf_exec("cmd %p releases child func at %p\n", command, command->child_func);
command->child_func->parent_cmd = NULL;
}
#endif
#if !BB_MMU
free(command->group_as_string);
command->group_as_string = NULL;
#endif
for (r = command->redirects; r; r = rnext) {
debug_printf_clean(" redirect %d%s",
r->rd_fd, redir_table[r->rd_type].descrip);
/* guard against the case >$FOO, where foo is unset or blank */
if (r->rd_filename) {
debug_printf_clean(" fname:'%s'\n", r->rd_filename);
free(r->rd_filename);
r->rd_filename = NULL;
}
debug_printf_clean(" rd_dup:%d\n", r->rd_dup);
rnext = r->next;
free(r);
}
command->redirects = NULL;
}
free(pi->cmds); /* children are an array, they get freed all at once */
pi->cmds = NULL;
#if ENABLE_HUSH_JOB
free(pi->cmdtext);
pi->cmdtext = NULL;
#endif
}
static void free_pipe_list(struct pipe *head)
{
struct pipe *pi, *next;
for (pi = head; pi; pi = next) {
#if HAS_KEYWORDS
debug_printf_clean(" pipe reserved word %d\n", pi->res_word);
#endif
free_pipe(pi);
debug_printf_clean("pipe followup code %d\n", pi->followup);
next = pi->next;
/*pi->next = NULL;*/
free(pi);
}
}
static int run_list(struct pipe *pi);
#if BB_MMU
#define parse_stream(pstring, input, end_trigger) \
parse_stream(input, end_trigger)
#endif
static struct pipe *parse_stream(char **pstring,
struct in_str *input,
int end_trigger);
static void parse_and_run_string(const char *s);
static const struct built_in_command* find_builtin(const char *name)
{
const struct built_in_command *x;
for (x = bltins; x != &bltins[ARRAY_SIZE(bltins)]; x++) {
if (strcmp(name, x->cmd) != 0)
continue;
debug_printf_exec("found builtin '%s'\n", name);
return x;
}
return NULL;
}
#if ENABLE_HUSH_FUNCTIONS
static const struct function *find_function(const char *name)
{
const struct function *funcp = G.top_func;
while (funcp) {
if (strcmp(name, funcp->name) == 0) {
break;
}
funcp = funcp->next;
}
debug_printf_exec("found function '%s'\n", name);
return funcp;
}
/* Note: takes ownership on name ptr */
static struct function *new_function(char *name)
{
struct function *funcp;
struct function **funcpp = &G.top_func;
while ((funcp = *funcpp) != NULL) {
struct command *cmd;
if (strcmp(funcp->name, name) != 0) {
funcpp = &funcp->next;
continue;
}
cmd = funcp->parent_cmd;
debug_printf_exec("func %p parent_cmd %p\n", funcp, cmd);
if (!cmd) {
debug_printf_exec("freeing & replacing function '%s'\n", funcp->name);
free(funcp->name);
/* Note: if !funcp->body, do not free body_as_string!
* This is a special case of "-F name body" function:
* body_as_string was not malloced! */
if (funcp->body) {
free_pipe_list(funcp->body);
#if !BB_MMU
free(funcp->body_as_string);
#endif
}
} else {
debug_printf_exec("reinserting in tree & replacing function '%s'\n", funcp->name);
cmd->argv[0] = funcp->name;
cmd->group = funcp->body;
#if !BB_MMU
cmd->group_as_string = funcp->body_as_string;
#endif
}
goto skip;
}
debug_printf_exec("remembering new function '%s'\n", command->argv[0]);
funcp = *funcpp = xzalloc(sizeof(*funcp));
/*funcp->next = NULL;*/
skip:
funcp->name = name;
return funcp;
}
#if BB_MMU
#define exec_function(nommu_save, funcp, argv) \
exec_function(funcp, argv)
#endif
static void exec_function(nommu_save_t *nommu_save,
const struct function *funcp,
char **argv) NORETURN;
static void exec_function(nommu_save_t *nommu_save,
const struct function *funcp,
char **argv)
{
# if BB_MMU
int n = 1;
argv[0] = G.global_argv[0];
G.global_argv = argv;
while (*++argv)
n++;
G.global_argc = n;
/* On MMU, funcp->body is always non-NULL */
n = run_list(funcp->body);
fflush(NULL);
_exit(n);
# else
re_execute_shell(&nommu_save->argv_from_re_execing,
funcp->body_as_string,
G.global_argv[0],
argv + 1);
# endif
}
static int run_function(const struct function *funcp, char **argv)
{
int n;
char **pp;
char *sv_argv0;
smallint sv_g_malloced;
int sv_g_argc;
char **sv_g_argv;
sv_argv0 = argv[0];
sv_g_malloced = G.global_args_malloced;
sv_g_argc = G.global_argc;
sv_g_argv = G.global_argv;
pp = argv;
n = 1;
while (*++pp)
n++;
argv[0] = G.global_argv[0]; /* retain $0 */
G.global_args_malloced = 0;
G.global_argc = n;
G.global_argv = argv;
/* On MMU, funcp->body is always non-NULL */
#if !BB_MMU
if (!funcp->body) {
/* Function defined by -F */
parse_and_run_string(funcp->body_as_string);
n = G.last_exitcode;
} else
#endif
{
n = run_list(funcp->body);
}
if (G.global_args_malloced) {
/* function ran "set -- arg1 arg2 ..." */
pp = G.global_argv;
while (*++pp)
free(*pp);
free(G.global_argv);
}
argv[0] = sv_argv0;
G.global_args_malloced = sv_g_malloced;
G.global_argc = sv_g_argc;
G.global_argv = sv_g_argv;
return n;
}
#endif
#if BB_MMU
#define pseudo_exec_argv(nommu_save, argv, assignment_cnt, argv_expanded) \
pseudo_exec_argv(argv, assignment_cnt, argv_expanded)
#define pseudo_exec(nommu_save, command, argv_expanded) \
pseudo_exec(command, argv_expanded)
#endif
/* Called after [v]fork() in run_pipe, or from builtin_exec.
* Never returns.
* XXX no exit() here. If you don't exec, use _exit instead.
* The at_exit handlers apparently confuse the calling process,
* in particular stdin handling. Not sure why? -- because of vfork! (vda) */
static void pseudo_exec_argv(nommu_save_t *nommu_save,
char **argv, int assignment_cnt,
char **argv_expanded) NORETURN;
static void pseudo_exec_argv(nommu_save_t *nommu_save,
char **argv, int assignment_cnt,
char **argv_expanded)
{
char **new_env;
/* Case when we are here: ... | var=val | ... */
if (!argv[assignment_cnt])
_exit(EXIT_SUCCESS);
new_env = expand_assignments(argv, assignment_cnt);
#if BB_MMU
putenv_all(new_env);
free(new_env); /* optional */
#else
nommu_save->new_env = new_env;
nommu_save->old_env = putenv_all_and_save_old(new_env);
#endif
if (argv_expanded) {
argv = argv_expanded;
} else {
argv = expand_strvec_to_strvec(argv + assignment_cnt);
#if !BB_MMU
nommu_save->argv = argv;
#endif
}
#if ENABLE_FEATURE_SH_STANDALONE || BB_MMU
if (strchr(argv[0], '/') != NULL)
goto skip;
#endif
/* On NOMMU, we must never block!
* Example: { sleep 99999 | read line } & echo Ok
* read builtin will block on read syscall, leaving parent blocked
* in vfork. Therefore we can't do this:
*/
#if BB_MMU
/* Check if the command matches any of the builtins.
* Depending on context, this might be redundant. But it's
* easier to waste a few CPU cycles than it is to figure out
* if this is one of those cases.
*/
{
int rcode;
const struct built_in_command *x = find_builtin(argv[0]);
if (x) {
rcode = x->function(argv);
fflush(NULL);
_exit(rcode);
}
}
#endif
#if ENABLE_HUSH_FUNCTIONS
/* Check if the command matches any functions */
{
const struct function *funcp = find_function(argv[0]);
if (funcp) {
exec_function(nommu_save, funcp, argv);
}
}
#endif
#if ENABLE_FEATURE_SH_STANDALONE
/* Check if the command matches any busybox applets */
{
int a = find_applet_by_name(argv[0]);
if (a >= 0) {
# if BB_MMU /* see above why on NOMMU it is not allowed */
if (APPLET_IS_NOEXEC(a)) {
debug_printf_exec("running applet '%s'\n", argv[0]);
run_applet_no_and_exit(a, argv);
}
# endif
/* Re-exec ourselves */
debug_printf_exec("re-execing applet '%s'\n", argv[0]);
sigprocmask(SIG_SETMASK, &G.inherited_set, NULL);
execv(bb_busybox_exec_path, argv);
/* If they called chroot or otherwise made the binary no longer
* executable, fall through */
}
}
#endif
#if ENABLE_FEATURE_SH_STANDALONE || BB_MMU
skip:
#endif
debug_printf_exec("execing '%s'\n", argv[0]);
sigprocmask(SIG_SETMASK, &G.inherited_set, NULL);
execvp(argv[0], argv);
bb_perror_msg("can't exec '%s'", argv[0]);
_exit(EXIT_FAILURE);
}
/* Called after [v]fork() in run_pipe
*/
static void pseudo_exec(nommu_save_t *nommu_save,
struct command *command,
char **argv_expanded) NORETURN;
static void pseudo_exec(nommu_save_t *nommu_save,
struct command *command,
char **argv_expanded)
{
if (command->argv) {
pseudo_exec_argv(nommu_save, command->argv,
command->assignment_cnt, argv_expanded);
}
if (command->group) {
/* Cases when we are here:
* ( list )
* { list } &
* ... | ( list ) | ...
* ... | { list } | ...
*/
#if BB_MMU
int rcode;
debug_printf_exec("pseudo_exec: run_list\n");
reset_traps_to_defaults();
rcode = run_list(command->group);
/* OK to leak memory by not calling free_pipe_list,
* since this process is about to exit */
_exit(rcode);
#else
re_execute_shell(&nommu_save->argv_from_re_execing,
command->group_as_string,
G.global_argv[0],
G.global_argv + 1);
#endif
}
/* Case when we are here: ... | >file */
debug_printf_exec("pseudo_exec'ed null command\n");
_exit(EXIT_SUCCESS);
}
#if ENABLE_HUSH_JOB
static const char *get_cmdtext(struct pipe *pi)
{
char **argv;
char *p;
int len;
/* This is subtle. ->cmdtext is created only on first backgrounding.
* (Think "cat, <ctrl-z>, fg, <ctrl-z>, fg, <ctrl-z>...." here...)
* On subsequent bg argv is trashed, but we won't use it */
if (pi->cmdtext)
return pi->cmdtext;
argv = pi->cmds[0].argv;
if (!argv || !argv[0]) {
pi->cmdtext = xzalloc(1);
return pi->cmdtext;
}
len = 0;
do len += strlen(*argv) + 1; while (*++argv);
pi->cmdtext = p = xmalloc(len);
argv = pi->cmds[0].argv;
do {
len = strlen(*argv);
memcpy(p, *argv, len);
p += len;
*p++ = ' ';
} while (*++argv);
p[-1] = '\0';
return pi->cmdtext;
}
static void insert_bg_job(struct pipe *pi)
{
struct pipe *thejob;
int i;
/* Linear search for the ID of the job to use */
pi->jobid = 1;
for (thejob = G.job_list; thejob; thejob = thejob->next)
if (thejob->jobid >= pi->jobid)
pi->jobid = thejob->jobid + 1;
/* Add thejob to the list of running jobs */
if (!G.job_list) {
thejob = G.job_list = xmalloc(sizeof(*thejob));
} else {
for (thejob = G.job_list; thejob->next; thejob = thejob->next)
continue;
thejob->next = xmalloc(sizeof(*thejob));
thejob = thejob->next;
}
/* Physically copy the struct job */
memcpy(thejob, pi, sizeof(struct pipe));
thejob->cmds = xzalloc(sizeof(pi->cmds[0]) * pi->num_cmds);
/* We cannot copy entire pi->cmds[] vector! Double free()s will happen */
for (i = 0; i < pi->num_cmds; i++) {
// TODO: do we really need to have so many fields which are just dead weight
// at execution stage?
thejob->cmds[i].pid = pi->cmds[i].pid;
/* all other fields are not used and stay zero */
}
thejob->next = NULL;
thejob->cmdtext = xstrdup(get_cmdtext(pi));
/* We don't wait for background thejobs to return -- append it
to the list of backgrounded thejobs and leave it alone */
if (G_interactive_fd)
printf("[%d] %d %s\n", thejob->jobid, thejob->cmds[0].pid, thejob->cmdtext);
G.last_bg_pid = thejob->cmds[0].pid;
G.last_jobid = thejob->jobid;
}
static void remove_bg_job(struct pipe *pi)
{
struct pipe *prev_pipe;
if (pi == G.job_list) {
G.job_list = pi->next;
} else {
prev_pipe = G.job_list;
while (prev_pipe->next != pi)
prev_pipe = prev_pipe->next;
prev_pipe->next = pi->next;
}
if (G.job_list)
G.last_jobid = G.job_list->jobid;
else
G.last_jobid = 0;
}
/* Remove a backgrounded job */
static void delete_finished_bg_job(struct pipe *pi)
{
remove_bg_job(pi);
pi->stopped_cmds = 0;
free_pipe(pi);
free(pi);
}
#endif /* JOB */
/* Check to see if any processes have exited -- if they
* have, figure out why and see if a job has completed */
static int checkjobs(struct pipe* fg_pipe)
{
int attributes;
int status;
#if ENABLE_HUSH_JOB
struct pipe *pi;
#endif
pid_t childpid;
int rcode = 0;
debug_printf_jobs("checkjobs %p\n", fg_pipe);
errno = 0;
// if (G.handled_SIGCHLD == G.count_SIGCHLD)
// /* avoid doing syscall, nothing there anyway */
// return rcode;
attributes = WUNTRACED;
if (fg_pipe == NULL)
attributes |= WNOHANG;
/* Do we do this right?
* bash-3.00# sleep 20 | false
* <ctrl-Z pressed>
* [3]+ Stopped sleep 20 | false
* bash-3.00# echo $?
* 1 <========== bg pipe is not fully done, but exitcode is already known!
*/
//FIXME: non-interactive bash does not continue even if all processes in fg pipe
//are stopped. Testcase: "cat | cat" in a script (not on command line)
// + killall -STOP cat
wait_more:
while (1) {
int i;
int dead;
// i = G.count_SIGCHLD;
childpid = waitpid(-1, &status, attributes);
if (childpid <= 0) {
if (childpid && errno != ECHILD)
bb_perror_msg("waitpid");
// else /* Until next SIGCHLD, waitpid's are useless */
// G.handled_SIGCHLD = i;
break;
}
dead = WIFEXITED(status) || WIFSIGNALED(status);
#if DEBUG_JOBS
if (WIFSTOPPED(status))
debug_printf_jobs("pid %d stopped by sig %d (exitcode %d)\n",
childpid, WSTOPSIG(status), WEXITSTATUS(status));
if (WIFSIGNALED(status))
debug_printf_jobs("pid %d killed by sig %d (exitcode %d)\n",
childpid, WTERMSIG(status), WEXITSTATUS(status));
if (WIFEXITED(status))
debug_printf_jobs("pid %d exited, exitcode %d\n",
childpid, WEXITSTATUS(status));
#endif
/* Were we asked to wait for fg pipe? */
if (fg_pipe) {
for (i = 0; i < fg_pipe->num_cmds; i++) {
debug_printf_jobs("check pid %d\n", fg_pipe->cmds[i].pid);
if (fg_pipe->cmds[i].pid != childpid)
continue;
/* printf("process %d exit %d\n", i, WEXITSTATUS(status)); */
if (dead) {
fg_pipe->cmds[i].pid = 0;
fg_pipe->alive_cmds--;
if (i == fg_pipe->num_cmds - 1) {
/* last process gives overall exitstatus */
rcode = WEXITSTATUS(status);
IF_HAS_KEYWORDS(if (fg_pipe->pi_inverted) rcode = !rcode;)
}
} else {
fg_pipe->cmds[i].is_stopped = 1;
fg_pipe->stopped_cmds++;
}
debug_printf_jobs("fg_pipe: alive_cmds %d stopped_cmds %d\n",
fg_pipe->alive_cmds, fg_pipe->stopped_cmds);
if (fg_pipe->alive_cmds - fg_pipe->stopped_cmds <= 0) {
/* All processes in fg pipe have exited/stopped */
#if ENABLE_HUSH_JOB
if (fg_pipe->alive_cmds)
insert_bg_job(fg_pipe);
#endif
return rcode;
}
/* There are still running processes in the fg pipe */
goto wait_more; /* do waitpid again */
}
/* it wasnt fg_pipe, look for process in bg pipes */
}
#if ENABLE_HUSH_JOB
/* We asked to wait for bg or orphaned children */
/* No need to remember exitcode in this case */
for (pi = G.job_list; pi; pi = pi->next) {
for (i = 0; i < pi->num_cmds; i++) {
if (pi->cmds[i].pid == childpid)
goto found_pi_and_prognum;
}
}
/* Happens when shell is used as init process (init=/bin/sh) */
debug_printf("checkjobs: pid %d was not in our list!\n", childpid);
continue; /* do waitpid again */
found_pi_and_prognum:
if (dead) {
/* child exited */
pi->cmds[i].pid = 0;
pi->alive_cmds--;
if (!pi->alive_cmds) {
if (G_interactive_fd)
printf(JOB_STATUS_FORMAT, pi->jobid,
"Done", pi->cmdtext);
delete_finished_bg_job(pi);
}
} else {
/* child stopped */
pi->cmds[i].is_stopped = 1;
pi->stopped_cmds++;
}
#endif
} /* while (waitpid succeeds)... */
return rcode;
}
#if ENABLE_HUSH_JOB
static int checkjobs_and_fg_shell(struct pipe* fg_pipe)
{
pid_t p;
int rcode = checkjobs(fg_pipe);
/* Job finished, move the shell to the foreground */
p = getpgid(0); /* pgid of our process */
debug_printf_jobs("fg'ing ourself: getpgid(0)=%d\n", (int)p);
tcsetpgrp(G_interactive_fd, p);
return rcode;
}
#endif
/* Start all the jobs, but don't wait for anything to finish.
* See checkjobs().
*
* Return code is normally -1, when the caller has to wait for children
* to finish to determine the exit status of the pipe. If the pipe
* is a simple builtin command, however, the action is done by the
* time run_pipe returns, and the exit code is provided as the
* return value.
*
* Returns -1 only if started some children. IOW: we have to
* mask out retvals of builtins etc with 0xff!
*
* The only case when we do not need to [v]fork is when the pipe
* is single, non-backgrounded, non-subshell command. Examples:
* cmd ; ... { list } ; ...
* cmd && ... { list } && ...
* cmd || ... { list } || ...
* If it is, then we can run cmd as a builtin, NOFORK [do we do this?],
* or (if SH_STANDALONE) an applet, and we can run the { list }
* with run_list(). If it isn't one of these, we fork and exec cmd.
*
* Cases when we must fork:
* non-single: cmd | cmd
* backgrounded: cmd & { list } &
* subshell: ( list ) [&]
*/
static int run_pipe(struct pipe *pi)
{
static const char *const null_ptr = NULL;
int i;
int nextin;
int pipefds[2]; /* pipefds[0] is for reading */
struct command *command;
char **argv_expanded;
char **argv;
char *p;
/* it is not always needed, but we aim to smaller code */
int squirrel[] = { -1, -1, -1 };
int rcode;
debug_printf_exec("run_pipe start: members:%d\n", pi->num_cmds);
debug_enter();
USE_HUSH_JOB(pi->pgrp = -1;)
pi->stopped_cmds = 0;
command = &(pi->cmds[0]);
argv_expanded = NULL;
if (pi->num_cmds != 1
|| pi->followup == PIPE_BG
|| command->grp_type == GRP_SUBSHELL
) {
goto must_fork;
}
pi->alive_cmds = 1;
debug_printf_exec(": group:%p argv:'%s'\n",
command->group, command->argv ? command->argv[0] : "NONE");
if (command->group) {
#if ENABLE_HUSH_FUNCTIONS
if (command->grp_type == GRP_FUNCTION) {
/* "executing" func () { list } */
struct function *funcp;
funcp = new_function(command->argv[0]);
/* funcp->name is already set to argv[0] */
funcp->body = command->group;
#if !BB_MMU
funcp->body_as_string = command->group_as_string;
command->group_as_string = NULL;
#endif
command->group = NULL;
command->argv[0] = NULL;
debug_printf_exec("cmd %p has child func at %p\n", command, funcp);
funcp->parent_cmd = command;
command->child_func = funcp;
debug_printf_exec("run_pipe: return EXIT_SUCCESS\n");
debug_leave();
return EXIT_SUCCESS;
}
#endif
/* { list } */
debug_printf("non-subshell group\n");
rcode = 1; /* exitcode if redir failed */
if (setup_redirects(command, squirrel) == 0) {
debug_printf_exec(": run_list\n");
rcode = run_list(command->group) & 0xff;
}
restore_redirects(squirrel);
IF_HAS_KEYWORDS(if (pi->pi_inverted) rcode = !rcode;)
debug_leave();
debug_printf_exec("run_pipe: return %d\n", rcode);
return rcode;
}
argv = command->argv ? command->argv : (char **) &null_ptr;
{
const struct built_in_command *x;
#if ENABLE_HUSH_FUNCTIONS
const struct function *funcp;
#else
enum { funcp = 0 };
#endif
char **new_env = NULL;
char **old_env = NULL;
if (argv[command->assignment_cnt] == NULL) {
/* Assignments, but no command */
/* Ensure redirects take effect. Try "a=t >file" */
rcode = setup_redirects(command, squirrel);
restore_redirects(squirrel);
/* Set shell variables */
while (*argv) {
p = expand_string_to_string(*argv);
debug_printf_exec("set shell var:'%s'->'%s'\n",
*argv, p);
set_local_var(p, 0, 0);
argv++;
}
/* Do we need to flag set_local_var() errors?
* "assignment to readonly var" and "putenv error"
*/
IF_HAS_KEYWORDS(if (pi->pi_inverted) rcode = !rcode;)
debug_leave();
debug_printf_exec("run_pipe: return %d\n", rcode);
return rcode;
}
/* Expand the rest into (possibly) many strings each */
argv_expanded = expand_strvec_to_strvec(argv + command->assignment_cnt);
x = find_builtin(argv_expanded[0]);
#if ENABLE_HUSH_FUNCTIONS
funcp = NULL;
if (!x)
funcp = find_function(argv_expanded[0]);
#endif
if (x || funcp) {
if (!funcp) {
if (x->function == builtin_exec && argv_expanded[1] == NULL) {
debug_printf("exec with redirects only\n");
rcode = setup_redirects(command, NULL);
goto clean_up_and_ret1;
}
}
/* XXX setup_redirects acts on file descriptors, not FILEs.
* This is perfect for work that comes after exec().
* Is it really safe for inline use? Experimentally,
* things seem to work with glibc. */
rcode = setup_redirects(command, squirrel);
if (rcode == 0) {
new_env = expand_assignments(argv, command->assignment_cnt);
old_env = putenv_all_and_save_old(new_env);
if (!funcp) {
debug_printf_exec(": builtin '%s' '%s'...\n",
x->cmd, argv_expanded[1]);
rcode = x->function(argv_expanded) & 0xff;
}
#if ENABLE_HUSH_FUNCTIONS
else {
debug_printf_exec(": function '%s' '%s'...\n",
funcp->name, argv_expanded[1]);
rcode = run_function(funcp, argv_expanded) & 0xff;
}
#endif
}
#if ENABLE_FEATURE_SH_STANDALONE
clean_up_and_ret:
#endif
restore_redirects(squirrel);
free_strings_and_unsetenv(new_env, 1);
putenv_all(old_env);
/* Free the pointers, but the strings themselves
* are in environ now, don't use free_strings! */
free(old_env);
clean_up_and_ret1:
free(argv_expanded);
IF_HAS_KEYWORDS(if (pi->pi_inverted) rcode = !rcode;)
debug_leave();
debug_printf_exec("run_pipe return %d\n", rcode);
return rcode;
}
#if ENABLE_FEATURE_SH_STANDALONE
i = find_applet_by_name(argv_expanded[0]);
if (i >= 0 && APPLET_IS_NOFORK(i)) {
rcode = setup_redirects(command, squirrel);
if (rcode == 0) {
new_env = expand_assignments(argv, command->assignment_cnt);
old_env = putenv_all_and_save_old(new_env);
debug_printf_exec(": run_nofork_applet '%s' '%s'...\n",
argv_expanded[0], argv_expanded[1]);
rcode = run_nofork_applet(i, argv_expanded);
}
goto clean_up_and_ret;
}
#endif
/* It is neither builtin nor applet. We must fork. */
}
must_fork:
/* NB: argv_expanded may already be created, and that
* might include `cmd` runs! Do not rerun it! We *must*
* use argv_expanded if it's non-NULL */
/* Going to fork a child per each pipe member */
pi->alive_cmds = 0;
nextin = 0;
for (i = 0; i < pi->num_cmds; i++) {
#if !BB_MMU
volatile nommu_save_t nommu_save;
nommu_save.new_env = NULL;
nommu_save.old_env = NULL;
nommu_save.argv = NULL;
nommu_save.argv_from_re_execing = NULL;
#endif
command = &(pi->cmds[i]);
if (command->argv) {
debug_printf_exec(": pipe member '%s' '%s'...\n",
command->argv[0], command->argv[1]);
} else {
debug_printf_exec(": pipe member with no argv\n");
}
/* pipes are inserted between pairs of commands */
pipefds[0] = 0;
pipefds[1] = 1;
if ((i + 1) < pi->num_cmds)
xpipe(pipefds);
command->pid = BB_MMU ? fork() : vfork();
if (!command->pid) { /* child */
#if ENABLE_HUSH_JOB
disable_restore_tty_pgrp_on_exit();
/* Every child adds itself to new process group
* with pgid == pid_of_first_child_in_pipe */
if (G.run_list_level == 1 && G_interactive_fd) {
pid_t pgrp;
pgrp = pi->pgrp;
if (pgrp < 0) /* true for 1st process only */
pgrp = getpid();
if (setpgid(0, pgrp) == 0 && pi->followup != PIPE_BG) {
/* We do it in *every* child, not just first,
* to avoid races */
tcsetpgrp(G_interactive_fd, pgrp);
}
}
#endif
xmove_fd(nextin, 0);
xmove_fd(pipefds[1], 1); /* write end */
if (pipefds[0] > 1)
close(pipefds[0]); /* read end */
/* Like bash, explicit redirects override pipes,
* and the pipe fd is available for dup'ing. */
if (setup_redirects(command, NULL))
_exit(1);
/* Restore default handlers just prior to exec */
/*signal(SIGCHLD, SIG_DFL); - so far we don't have any handlers */
/* Stores to nommu_save list of env vars putenv'ed
* (NOMMU, on MMU we don't need that) */
/* cast away volatility... */
pseudo_exec((nommu_save_t*) &nommu_save, command, argv_expanded);
/* pseudo_exec() does not return */
}
/* parent or error */
enable_restore_tty_pgrp_on_exit();
#if !BB_MMU
/* Clean up after vforked child */
free(nommu_save.argv);
free(nommu_save.argv_from_re_execing);
free_strings_and_unsetenv(nommu_save.new_env, 1);
putenv_all(nommu_save.old_env);
/* Free the pointers, but the strings themselves
* are in environ now, don't use free_strings! */
free(nommu_save.old_env);
#endif
free(argv_expanded);
argv_expanded = NULL;
if (command->pid < 0) { /* [v]fork failed */
/* Clearly indicate, was it fork or vfork */
bb_perror_msg(BB_MMU ? "fork" : "vfork");
} else {
pi->alive_cmds++;
#if ENABLE_HUSH_JOB
/* Second and next children need to know pid of first one */
if (pi->pgrp < 0)
pi->pgrp = command->pid;
#endif
}
if (i)
close(nextin);
if ((i + 1) < pi->num_cmds)
close(pipefds[1]); /* write end */
/* Pass read (output) pipe end to next iteration */
nextin = pipefds[0];
}
if (!pi->alive_cmds) {
debug_leave();
debug_printf_exec("run_pipe return 1 (all forks failed, no children)\n");
return 1;
}
debug_leave();
debug_printf_exec("run_pipe return -1 (%u children started)\n", pi->alive_cmds);
return -1;
}
#ifndef debug_print_tree
static void debug_print_tree(struct pipe *pi, int lvl)
{
static const char *const PIPE[] = {
[PIPE_SEQ] = "SEQ",
[PIPE_AND] = "AND",
[PIPE_OR ] = "OR" ,
[PIPE_BG ] = "BG" ,
};
static const char *RES[] = {
[RES_NONE ] = "NONE" ,
#if ENABLE_HUSH_IF
[RES_IF ] = "IF" ,
[RES_THEN ] = "THEN" ,
[RES_ELIF ] = "ELIF" ,
[RES_ELSE ] = "ELSE" ,
[RES_FI ] = "FI" ,
#endif
#if ENABLE_HUSH_LOOPS
[RES_FOR ] = "FOR" ,
[RES_WHILE] = "WHILE",
[RES_UNTIL] = "UNTIL",
[RES_DO ] = "DO" ,
[RES_DONE ] = "DONE" ,
#endif
#if ENABLE_HUSH_LOOPS || ENABLE_HUSH_CASE
[RES_IN ] = "IN" ,
#endif
#if ENABLE_HUSH_CASE
[RES_CASE ] = "CASE" ,
[RES_MATCH] = "MATCH",
[RES_CASEI] = "CASEI",
[RES_ESAC ] = "ESAC" ,
#endif
[RES_XXXX ] = "XXXX" ,
[RES_SNTX ] = "SNTX" ,
};
static const char *const GRPTYPE[] = {
"{}",
"()",
#if ENABLE_HUSH_FUNCTIONS
"func()",
#endif
};
int pin, prn;
pin = 0;
while (pi) {
fprintf(stderr, "%*spipe %d res_word=%s followup=%d %s\n", lvl*2, "",
pin, RES[pi->res_word], pi->followup, PIPE[pi->followup]);
prn = 0;
while (prn < pi->num_cmds) {
struct command *command = &pi->cmds[prn];
char **argv = command->argv;
fprintf(stderr, "%*s cmd %d assignment_cnt:%d",
lvl*2, "", prn,
command->assignment_cnt);
if (command->group) {
fprintf(stderr, " group %s: (argv=%p)\n",
GRPTYPE[command->grp_type],
argv);
debug_print_tree(command->group, lvl+1);
prn++;
continue;
}
if (argv) while (*argv) {
fprintf(stderr, " '%s'", *argv);
argv++;
}
fprintf(stderr, "\n");
prn++;
}
pi = pi->next;
pin++;
}
}
#endif
/* NB: called by pseudo_exec, and therefore must not modify any
* global data until exec/_exit (we can be a child after vfork!) */
static int run_list(struct pipe *pi)
{
#if ENABLE_HUSH_CASE
char *case_word = NULL;
#endif
#if ENABLE_HUSH_LOOPS
struct pipe *loop_top = NULL;
char *for_varname = NULL;
char **for_lcur = NULL;
char **for_list = NULL;
#endif
smallint last_followup;
smalluint rcode;
#if ENABLE_HUSH_IF || ENABLE_HUSH_CASE
smalluint cond_code = 0;
#else
enum { cond_code = 0 };
#endif
#if HAS_KEYWORDS
smallint rword; /* enum reserved_style */
smallint last_rword; /* ditto */
#endif
debug_printf_exec("run_list start lvl %d\n", G.run_list_level);
debug_enter();
#if ENABLE_HUSH_LOOPS
/* Check syntax for "for" */
for (struct pipe *cpipe = pi; cpipe; cpipe = cpipe->next) {
if (cpipe->res_word != RES_FOR && cpipe->res_word != RES_IN)
continue;
/* current word is FOR or IN (BOLD in comments below) */
if (cpipe->next == NULL) {
syntax_error("malformed for");
debug_leave();
debug_printf_exec("run_list lvl %d return 1\n", G.run_list_level);
return 1;
}
/* "FOR v; do ..." and "for v IN a b; do..." are ok */
if (cpipe->next->res_word == RES_DO)
continue;
/* next word is not "do". It must be "in" then ("FOR v in ...") */
if (cpipe->res_word == RES_IN /* "for v IN a b; not_do..."? */
|| cpipe->next->res_word != RES_IN /* FOR v not_do_and_not_in..."? */
) {
syntax_error("malformed for");
debug_leave();
debug_printf_exec("run_list lvl %d return 1\n", G.run_list_level);
return 1;
}
}
#endif
/* Past this point, all code paths should jump to ret: label
* in order to return, no direct "return" statements please.
* This helps to ensure that no memory is leaked. */
#if ENABLE_HUSH_JOB
G.run_list_level++;
#endif
#if HAS_KEYWORDS
rword = RES_NONE;
last_rword = RES_XXXX;
#endif
last_followup = PIPE_SEQ;
rcode = G.last_exitcode;
/* Go through list of pipes, (maybe) executing them. */
for (; pi; pi = USE_HUSH_LOOPS(rword == RES_DONE ? loop_top : ) pi->next) {
if (G.flag_SIGINT)
break;
IF_HAS_KEYWORDS(rword = pi->res_word;)
debug_printf_exec(": rword=%d cond_code=%d last_rword=%d\n",
rword, cond_code, last_rword);
#if ENABLE_HUSH_LOOPS
if ((rword == RES_WHILE || rword == RES_UNTIL || rword == RES_FOR)
&& loop_top == NULL /* avoid bumping G.depth_of_loop twice */
) {
/* start of a loop: remember where loop starts */
loop_top = pi;
G.depth_of_loop++;
}
#endif
/* Still in the same "if...", "then..." or "do..." branch? */
if (IF_HAS_KEYWORDS(rword == last_rword &&) 1) {
if ((rcode == 0 && last_followup == PIPE_OR)
|| (rcode != 0 && last_followup == PIPE_AND)
) {
/* It is "<true> || CMD" or "<false> && CMD"
* and we should not execute CMD */
debug_printf_exec("skipped cmd because of || or &&\n");
last_followup = pi->followup;
continue;
}
}
last_followup = pi->followup;
IF_HAS_KEYWORDS(last_rword = rword;)
#if ENABLE_HUSH_IF
if (cond_code) {
if (rword == RES_THEN) {
/* if false; then ... fi has exitcode 0! */
G.last_exitcode = rcode = EXIT_SUCCESS;
/* "if <false> THEN cmd": skip cmd */
continue;
}
} else {
if (rword == RES_ELSE || rword == RES_ELIF) {
/* "if <true> then ... ELSE/ELIF cmd":
* skip cmd and all following ones */
break;
}
}
#endif
#if ENABLE_HUSH_LOOPS
if (rword == RES_FOR) { /* && pi->num_cmds - always == 1 */
if (!for_lcur) {
/* first loop through for */
static const char encoded_dollar_at[] ALIGN1 = {
SPECIAL_VAR_SYMBOL, '@' | 0x80, SPECIAL_VAR_SYMBOL, '\0'
}; /* encoded representation of "$@" */
static const char *const encoded_dollar_at_argv[] = {
encoded_dollar_at, NULL
}; /* argv list with one element: "$@" */
char **vals;
vals = (char**)encoded_dollar_at_argv;
if (pi->next->res_word == RES_IN) {
/* if no variable values after "in" we skip "for" */
if (!pi->next->cmds[0].argv) {
G.last_exitcode = rcode = EXIT_SUCCESS;
debug_printf_exec(": null FOR: exitcode EXIT_SUCCESS\n");
break;
}
vals = pi->next->cmds[0].argv;
} /* else: "for var; do..." -> assume "$@" list */
/* create list of variable values */
debug_print_strings("for_list made from", vals);
for_list = expand_strvec_to_strvec(vals);
for_lcur = for_list;
debug_print_strings("for_list", for_list);
for_varname = pi->cmds[0].argv[0];
pi->cmds[0].argv[0] = NULL;
}
free(pi->cmds[0].argv[0]);
if (!*for_lcur) {
/* "for" loop is over, clean up */
free(for_list);
for_list = NULL;
for_lcur = NULL;
pi->cmds[0].argv[0] = for_varname;
break;
}
/* Insert next value from for_lcur */
/* note: *for_lcur already has quotes removed, $var expanded, etc */
pi->cmds[0].argv[0] = xasprintf("%s=%s", for_varname, *for_lcur++);
pi->cmds[0].assignment_cnt = 1;
}
if (rword == RES_IN) {
continue; /* "for v IN list;..." - "in" has no cmds anyway */
}
if (rword == RES_DONE) {
continue; /* "done" has no cmds too */
}
#endif
#if ENABLE_HUSH_CASE
if (rword == RES_CASE) {
case_word = expand_strvec_to_string(pi->cmds->argv);
continue;
}
if (rword == RES_MATCH) {
char **argv;
if (!case_word) /* "case ... matched_word) ... WORD)": we executed selected branch, stop */
break;
/* all prev words didn't match, does this one match? */
argv = pi->cmds->argv;
while (*argv) {
char *pattern = expand_string_to_string(*argv);
/* TODO: which FNM_xxx flags to use? */
cond_code = (fnmatch(pattern, case_word, /*flags:*/ 0) != 0);
free(pattern);
if (cond_code == 0) { /* match! we will execute this branch */
free(case_word); /* make future "word)" stop */
case_word = NULL;
break;
}
argv++;
}
continue;
}
if (rword == RES_CASEI) { /* inside of a case branch */
if (cond_code != 0)
continue; /* not matched yet, skip this pipe */
}
#endif
/* Just pressing <enter> in shell should check for jobs.
* OTOH, in non-interactive shell this is useless
* and only leads to extra job checks */
if (pi->num_cmds == 0) {
if (G_interactive_fd)
goto check_jobs_and_continue;
continue;
}
/* After analyzing all keywords and conditions, we decided
* to execute this pipe. NB: have to do checkjobs(NULL)
* after run_pipe to collect any background children,
* even if list execution is to be stopped. */
debug_printf_exec(": run_pipe with %d members\n", pi->num_cmds);
{
int r;
#if ENABLE_HUSH_LOOPS
G.flag_break_continue = 0;
#endif
rcode = r = run_pipe(pi); /* NB: rcode is a smallint */
if (r != -1) {
/* We only ran a builtin: rcode is already known
* and we don't need to wait for anything. */
G.last_exitcode = rcode;
debug_printf_exec(": builtin/func exitcode %d\n", rcode);
check_and_run_traps(0);
#if ENABLE_HUSH_LOOPS
/* Was it "break" or "continue"? */
if (G.flag_break_continue) {
smallint fbc = G.flag_break_continue;
/* We might fall into outer *loop*,
* don't want to break it too */
if (loop_top) {
G.depth_break_continue--;
if (G.depth_break_continue == 0)
G.flag_break_continue = 0;
/* else: e.g. "continue 2" should *break* once, *then* continue */
} /* else: "while... do... { we are here (innermost list is not a loop!) };...done" */
if (G.depth_break_continue != 0 || fbc == BC_BREAK)
goto check_jobs_and_break;
/* "continue": simulate end of loop */
rword = RES_DONE;
continue;
}
#endif
} else if (pi->followup == PIPE_BG) {
/* What does bash do with attempts to background builtins? */
/* even bash 3.2 doesn't do that well with nested bg:
* try "{ { sleep 10; echo DEEP; } & echo HERE; } &".
* I'm NOT treating inner &'s as jobs */
check_and_run_traps(0);
#if ENABLE_HUSH_JOB
if (G.run_list_level == 1)
insert_bg_job(pi);
#endif
G.last_exitcode = rcode = EXIT_SUCCESS;
debug_printf_exec(": cmd&: exitcode EXIT_SUCCESS\n");
} else {
#if ENABLE_HUSH_JOB
if (G.run_list_level == 1 && G_interactive_fd) {
/* Waits for completion, then fg's main shell */
rcode = checkjobs_and_fg_shell(pi);
debug_printf_exec(": checkjobs_and_fg_shell exitcode %d\n", rcode);
check_and_run_traps(0);
} else
#endif
{ /* This one just waits for completion */
rcode = checkjobs(pi);
debug_printf_exec(": checkjobs exitcode %d\n", rcode);
check_and_run_traps(0);
}
G.last_exitcode = rcode;
}
}
/* Analyze how result affects subsequent commands */
#if ENABLE_HUSH_IF
if (rword == RES_IF || rword == RES_ELIF)
cond_code = rcode;
#endif
#if ENABLE_HUSH_LOOPS
/* Beware of "while false; true; do ..."! */
if (pi->next && pi->next->res_word == RES_DO) {
if (rword == RES_WHILE) {
if (rcode) {
/* "while false; do...done" - exitcode 0 */
G.last_exitcode = rcode = EXIT_SUCCESS;
debug_printf_exec(": while expr is false: breaking (exitcode:EXIT_SUCCESS)\n");
goto check_jobs_and_break;
}
}
if (rword == RES_UNTIL) {
if (!rcode) {
debug_printf_exec(": until expr is true: breaking\n");
check_jobs_and_break:
checkjobs(NULL);
break;
}
}
}
#endif
check_jobs_and_continue:
checkjobs(NULL);
} /* for (pi) */
#if ENABLE_HUSH_JOB
G.run_list_level--;
#endif
#if ENABLE_HUSH_LOOPS
if (loop_top)
G.depth_of_loop--;
free(for_list);
#endif
#if ENABLE_HUSH_CASE
free(case_word);
#endif
debug_leave();
debug_printf_exec("run_list lvl %d return %d\n", G.run_list_level + 1, rcode);
return rcode;
}
/* Select which version we will use */
static int run_and_free_list(struct pipe *pi)
{
int rcode = 0;
debug_printf_exec("run_and_free_list entered\n");
if (!G.fake_mode) {
debug_printf_exec(": run_list: 1st pipe with %d cmds\n", pi->num_cmds);
rcode = run_list(pi);
}
/* free_pipe_list has the side effect of clearing memory.
* In the long run that function can be merged with run_list,
* but doing that now would hobble the debugging effort. */
free_pipe_list(pi);
debug_printf_exec("run_and_free_list return %d\n", rcode);
return rcode;
}
static struct pipe *new_pipe(void)
{
struct pipe *pi;
pi = xzalloc(sizeof(struct pipe));
/*pi->followup = 0; - deliberately invalid value */
/*pi->res_word = RES_NONE; - RES_NONE is 0 anyway */
return pi;
}
/* Command (member of a pipe) is complete. The only possible error here
* is out of memory, in which case xmalloc exits. */
static int done_command(struct parse_context *ctx)
{
/* The command is really already in the pipe structure, so
* advance the pipe counter and make a new, null command. */
struct pipe *pi = ctx->pipe;
struct command *command = ctx->command;
if (command) {
if (command->group == NULL
&& command->argv == NULL
&& command->redirects == NULL
) {
debug_printf_parse("done_command: skipping null cmd, num_cmds=%d\n", pi->num_cmds);
memset(command, 0, sizeof(*command)); /* paranoia */
return pi->num_cmds;
}
pi->num_cmds++;
debug_printf_parse("done_command: ++num_cmds=%d\n", pi->num_cmds);
//debug_print_tree(ctx->list_head, 20);
} else {
debug_printf_parse("done_command: initializing, num_cmds=%d\n", pi->num_cmds);
}
/* Only real trickiness here is that the uncommitted
* command structure is not counted in pi->num_cmds. */
pi->cmds = xrealloc(pi->cmds, sizeof(*pi->cmds) * (pi->num_cmds+1));
command = &pi->cmds[pi->num_cmds];
memset(command, 0, sizeof(*command));
ctx->command = command;
/* but ctx->pipe and ctx->list_head remain unchanged */
return pi->num_cmds; /* used only for 0/nonzero check */
}
static void done_pipe(struct parse_context *ctx, pipe_style type)
{
int not_null;
debug_printf_parse("done_pipe entered, followup %d\n", type);
/* Close previous command */
not_null = done_command(ctx);
ctx->pipe->followup = type;
#if HAS_KEYWORDS
ctx->pipe->pi_inverted = ctx->ctx_inverted;
ctx->ctx_inverted = 0;
ctx->pipe->res_word = ctx->ctx_res_w;
#endif
/* Without this check, even just <enter> on command line generates
* tree of three NOPs (!). Which is harmless but annoying.
* IOW: it is safe to do it unconditionally.
* RES_NONE case is for "for a in; do ..." (empty IN set)
* and other cases to work. */
if (not_null
#if ENABLE_HUSH_IF
|| ctx->ctx_res_w == RES_FI
#endif
#if ENABLE_HUSH_LOOPS
|| ctx->ctx_res_w == RES_DONE
|| ctx->ctx_res_w == RES_FOR
|| ctx->ctx_res_w == RES_IN
#endif
#if ENABLE_HUSH_CASE
|| ctx->ctx_res_w == RES_ESAC
#endif
) {
struct pipe *new_p;
debug_printf_parse("done_pipe: adding new pipe: "
"not_null:%d ctx->ctx_res_w:%d\n",
not_null, ctx->ctx_res_w);
new_p = new_pipe();
ctx->pipe->next = new_p;
ctx->pipe = new_p;
/* RES_THEN, RES_DO etc are "sticky" -
* they remain set for commands inside if/while.
* This is used to control execution.
* RES_FOR and RES_IN are NOT sticky (needed to support
* cases where variable or value happens to match a keyword):
*/
#if ENABLE_HUSH_LOOPS
if (ctx->ctx_res_w == RES_FOR
|| ctx->ctx_res_w == RES_IN)
ctx->ctx_res_w = RES_NONE;
#endif
#if ENABLE_HUSH_CASE
if (ctx->ctx_res_w == RES_MATCH)
ctx->ctx_res_w = RES_CASEI;
#endif
ctx->command = NULL; /* trick done_command below */
/* Create the memory for command, roughly:
* ctx->pipe->cmds = new struct command;
* ctx->command = &ctx->pipe->cmds[0];
*/
done_command(ctx);
//debug_print_tree(ctx->list_head, 10);
}
debug_printf_parse("done_pipe return\n");
}
static void initialize_context(struct parse_context *ctx)
{
memset(ctx, 0, sizeof(*ctx));
ctx->pipe = ctx->list_head = new_pipe();
/* Create the memory for command, roughly:
* ctx->pipe->cmds = new struct command;
* ctx->command = &ctx->pipe->cmds[0];
*/
done_command(ctx);
}
/* If a reserved word is found and processed, parse context is modified
* and 1 is returned.
*/
#if HAS_KEYWORDS
struct reserved_combo {
char literal[6];
unsigned char res;
unsigned char assignment_flag;
int flag;
};
enum {
FLAG_END = (1 << RES_NONE ),
#if ENABLE_HUSH_IF
FLAG_IF = (1 << RES_IF ),
FLAG_THEN = (1 << RES_THEN ),
FLAG_ELIF = (1 << RES_ELIF ),
FLAG_ELSE = (1 << RES_ELSE ),
FLAG_FI = (1 << RES_FI ),
#endif
#if ENABLE_HUSH_LOOPS
FLAG_FOR = (1 << RES_FOR ),
FLAG_WHILE = (1 << RES_WHILE),
FLAG_UNTIL = (1 << RES_UNTIL),
FLAG_DO = (1 << RES_DO ),
FLAG_DONE = (1 << RES_DONE ),
FLAG_IN = (1 << RES_IN ),
#endif
#if ENABLE_HUSH_CASE
FLAG_MATCH = (1 << RES_MATCH),
FLAG_ESAC = (1 << RES_ESAC ),
#endif
FLAG_START = (1 << RES_XXXX ),
};
static const struct reserved_combo* match_reserved_word(o_string *word)
{
/* Mostly a list of accepted follow-up reserved words.
* FLAG_END means we are done with the sequence, and are ready
* to turn the compound list into a command.
* FLAG_START means the word must start a new compound list.
*/
static const struct reserved_combo reserved_list[] = {
#if ENABLE_HUSH_IF
{ "!", RES_NONE, NOT_ASSIGNMENT , 0 },
{ "if", RES_IF, WORD_IS_KEYWORD, FLAG_THEN | FLAG_START },
{ "then", RES_THEN, WORD_IS_KEYWORD, FLAG_ELIF | FLAG_ELSE | FLAG_FI },
{ "elif", RES_ELIF, WORD_IS_KEYWORD, FLAG_THEN },
{ "else", RES_ELSE, WORD_IS_KEYWORD, FLAG_FI },
{ "fi", RES_FI, NOT_ASSIGNMENT , FLAG_END },
#endif
#if ENABLE_HUSH_LOOPS
{ "for", RES_FOR, NOT_ASSIGNMENT , FLAG_IN | FLAG_DO | FLAG_START },
{ "while", RES_WHILE, WORD_IS_KEYWORD, FLAG_DO | FLAG_START },
{ "until", RES_UNTIL, WORD_IS_KEYWORD, FLAG_DO | FLAG_START },
{ "in", RES_IN, NOT_ASSIGNMENT , FLAG_DO },
{ "do", RES_DO, WORD_IS_KEYWORD, FLAG_DONE },
{ "done", RES_DONE, NOT_ASSIGNMENT , FLAG_END },
#endif
#if ENABLE_HUSH_CASE
{ "case", RES_CASE, NOT_ASSIGNMENT , FLAG_MATCH | FLAG_START },
{ "esac", RES_ESAC, NOT_ASSIGNMENT , FLAG_END },
#endif
};
const struct reserved_combo *r;
for (r = reserved_list; r < reserved_list + ARRAY_SIZE(reserved_list); r++) {
if (strcmp(word->data, r->literal) == 0)
return r;
}
return NULL;
}
static int reserved_word(o_string *word, struct parse_context *ctx)
{
#if ENABLE_HUSH_CASE
static const struct reserved_combo reserved_match = {
"", RES_MATCH, NOT_ASSIGNMENT , FLAG_MATCH | FLAG_ESAC
};
#endif
const struct reserved_combo *r;
r = match_reserved_word(word);
if (!r)
return 0;
debug_printf("found reserved word %s, res %d\n", r->literal, r->res);
#if ENABLE_HUSH_CASE
if (r->res == RES_IN && ctx->ctx_res_w == RES_CASE)
/* "case word IN ..." - IN part starts first match part */
r = &reserved_match;
else
#endif
if (r->flag == 0) { /* '!' */
if (ctx->ctx_inverted) { /* bash doesn't accept '! ! true' */
syntax_error("! ! command");
IF_HAS_KEYWORDS(ctx->ctx_res_w = RES_SNTX;)
}
ctx->ctx_inverted = 1;
return 1;
}
if (r->flag & FLAG_START) {
struct parse_context *old;
old = xmalloc(sizeof(*old));
debug_printf_parse("push stack %p\n", old);
*old = *ctx; /* physical copy */
initialize_context(ctx);
ctx->stack = old;
} else if (/*ctx->ctx_res_w == RES_NONE ||*/ !(ctx->old_flag & (1 << r->res))) {
syntax_error_at(word->data);
ctx->ctx_res_w = RES_SNTX;
return 1;
}
ctx->ctx_res_w = r->res;
ctx->old_flag = r->flag;
if (ctx->old_flag & FLAG_END) {
struct parse_context *old;
done_pipe(ctx, PIPE_SEQ);
debug_printf_parse("pop stack %p\n", ctx->stack);
old = ctx->stack;
old->command->group = ctx->list_head;
old->command->grp_type = GRP_NORMAL;
#if !BB_MMU
o_addstr(&old->as_string, ctx->as_string.data);
o_free_unsafe(&ctx->as_string);
old->command->group_as_string = xstrdup(old->as_string.data);
debug_printf_parse("pop, remembering as:'%s'\n",
old->command->group_as_string);
#endif
*ctx = *old; /* physical copy */
free(old);
}
word->o_assignment = r->assignment_flag;
return 1;
}
#endif
/* Word is complete, look at it and update parsing context.
* Normal return is 0. Syntax errors return 1.
* Note: on return, word is reset, but not o_free'd!
*/
static int done_word(o_string *word, struct parse_context *ctx)
{
struct command *command = ctx->command;
debug_printf_parse("done_word entered: '%s' %p\n", word->data, command);
if (word->length == 0 && word->o_quoted == 0) {
debug_printf_parse("done_word return 0: true null, ignored\n");
return 0;
}
if (ctx->pending_redirect) {
/* We do not glob in e.g. >*.tmp case. bash seems to glob here
* only if run as "bash", not "sh" */
/* http://www.opengroup.org/onlinepubs/009695399/utilities/xcu_chap02.html
* "2.7 Redirection
* ...the word that follows the redirection operator
* shall be subjected to tilde expansion, parameter expansion,
* command substitution, arithmetic expansion, and quote
* removal. Pathname expansion shall not be performed
* on the word by a non-interactive shell; an interactive
* shell may perform it, but shall do so only when
* the expansion would result in one word."
*/
ctx->pending_redirect->rd_filename = xstrdup(word->data);
/* Cater for >\file case:
* >\a creates file a; >\\a, >"\a", >"\\a" create file \a
* Same with heredocs:
* for <<\H delim is H; <<\\H, <<"\H", <<"\\H" - \H
*/
unbackslash(ctx->pending_redirect->rd_filename);
/* Is it <<"HEREDOC"? */
if (ctx->pending_redirect->rd_type == REDIRECT_HEREDOC
&& word->o_quoted
) {
ctx->pending_redirect->rd_dup |= HEREDOC_QUOTED;
}
debug_printf_parse("word stored in rd_filename: '%s'\n", word->data);
ctx->pending_redirect = NULL;
} else {
/* If this word wasn't an assignment, next ones definitely
* can't be assignments. Even if they look like ones. */
if (word->o_assignment != DEFINITELY_ASSIGNMENT
&& word->o_assignment != WORD_IS_KEYWORD
) {
word->o_assignment = NOT_ASSIGNMENT;
} else {
if (word->o_assignment == DEFINITELY_ASSIGNMENT)
command->assignment_cnt++;
word->o_assignment = MAYBE_ASSIGNMENT;
}
if (command->group) {
/* "{ echo foo; } echo bar" - bad */
/* NB: bash allows e.g.:
* if true; then { echo foo; } fi
* while if false; then false; fi do break; done
* and disallows:
* while if false; then false; fi; do; break; done
* TODO? */
syntax_error_at(word->data);
debug_printf_parse("done_word return 1: syntax error, "
"groups and arglists don't mix\n");
return 1;
}
#if HAS_KEYWORDS
# if ENABLE_HUSH_CASE
if (ctx->ctx_dsemicolon
&& strcmp(word->data, "esac") != 0 /* not "... pattern) cmd;; esac" */
) {
/* already done when ctx_dsemicolon was set to 1: */
/* ctx->ctx_res_w = RES_MATCH; */
ctx->ctx_dsemicolon = 0;
} else
# endif
if (!command->argv /* if it's the first word... */
# if ENABLE_HUSH_LOOPS
&& ctx->ctx_res_w != RES_FOR /* ...not after FOR or IN */
&& ctx->ctx_res_w != RES_IN
# endif
) {
debug_printf_parse(": checking '%s' for reserved-ness\n", word->data);
if (reserved_word(word, ctx)) {
o_reset_to_empty_unquoted(word);
debug_printf_parse("done_word return %d\n",
(ctx->ctx_res_w == RES_SNTX));
return (ctx->ctx_res_w == RES_SNTX);
}
}
#endif
if (word->o_quoted /* word had "xx" or 'xx' at least as part of it. */
/* optimization: and if it's ("" or '') or ($v... or `cmd`...): */
&& (word->data[0] == '\0' || word->data[0] == SPECIAL_VAR_SYMBOL)
/* (otherwise it's known to be not empty and is already safe) */
) {
/* exclude "$@" - it can expand to no word despite "" */
char *p = word->data;
while (p[0] == SPECIAL_VAR_SYMBOL
&& (p[1] & 0x7f) == '@'
&& p[2] == SPECIAL_VAR_SYMBOL
) {
p += 3;
}
if (p == word->data || p[0] != '\0') {
/* saw no "$@", or not only "$@" but some
* real text is there too */
/* insert "empty variable" reference, this makes
* e.g. "", $empty"" etc to not disappear */
o_addchr(word, SPECIAL_VAR_SYMBOL);
o_addchr(word, SPECIAL_VAR_SYMBOL);
}
}
command->argv = add_string_to_strings(command->argv, xstrdup(word->data));
//SEGV, but good idea.
// command->argv = add_string_to_strings(command->argv, word->data);
// word->data = NULL;
// word->length = 0;
debug_print_strings("word appended to argv", command->argv);
}
#if ENABLE_HUSH_LOOPS
if (ctx->ctx_res_w == RES_FOR) {
if (word->o_quoted
|| !is_well_formed_var_name(command->argv[0], '\0')
) {
/* bash says just "not a valid identifier" */
syntax_error("not a valid identifier in for");
return 1;
}
/* Force FOR to have just one word (variable name) */
/* NB: basically, this makes hush see "for v in ..."
* syntax as if it is "for v; in ...". FOR and IN become
* two pipe structs in parse tree. */
done_pipe(ctx, PIPE_SEQ);
}
#endif
#if ENABLE_HUSH_CASE
/* Force CASE to have just one word */
if (ctx->ctx_res_w == RES_CASE) {
done_pipe(ctx, PIPE_SEQ);
}
#endif
o_reset_to_empty_unquoted(word);
debug_printf_parse("done_word return 0\n");
return 0;
}
/* Peek ahead in the input to find out if we have a "&n" construct,
* as in "2>&1", that represents duplicating a file descriptor.
* Return:
* REDIRFD_CLOSE if >&- "close fd" construct is seen,
* REDIRFD_SYNTAX_ERR if syntax error,
* REDIRFD_TO_FILE if no & was seen,
* or the number found.
*/
#if BB_MMU
#define parse_redir_right_fd(as_string, input) \
parse_redir_right_fd(input)
#endif
static int parse_redir_right_fd(o_string *as_string, struct in_str *input)
{
int ch, d, ok;
ch = i_peek(input);
if (ch != '&')
return REDIRFD_TO_FILE;
ch = i_getch(input); /* get the & */
nommu_addchr(as_string, ch);
ch = i_peek(input);
if (ch == '-') {
ch = i_getch(input);
nommu_addchr(as_string, ch);
return REDIRFD_CLOSE;
}
d = 0;
ok = 0;
while (ch != EOF && isdigit(ch)) {
d = d*10 + (ch-'0');
ok = 1;
ch = i_getch(input);
nommu_addchr(as_string, ch);
ch = i_peek(input);
}
if (ok) return d;
//TODO: this is the place to catch ">&file" bashism (redirect both fd 1 and 2)
bb_error_msg("ambiguous redirect");
return REDIRFD_SYNTAX_ERR;
}
/* Return code is 0 normal, 1 if a syntax error is detected
*/
static int parse_redirect(struct parse_context *ctx,
int fd,
redir_type style,
struct in_str *input)
{
struct command *command = ctx->command;
struct redir_struct *redir;
struct redir_struct **redirp;
int dup_num;
dup_num = REDIRFD_TO_FILE;
if (style != REDIRECT_HEREDOC) {
/* Check for a '>&1' type redirect */
dup_num = parse_redir_right_fd(&ctx->as_string, input);
if (dup_num == REDIRFD_SYNTAX_ERR)
return 1;
} else {
int ch = i_peek(input);
dup_num = (ch == '-'); /* HEREDOC_SKIPTABS bit is 1 */
if (dup_num) { /* <<-... */
ch = i_getch(input);
nommu_addchr(&ctx->as_string, ch);
ch = i_peek(input);
}
}
if (style == REDIRECT_OVERWRITE && dup_num == REDIRFD_TO_FILE) {
int ch = i_peek(input);
if (ch == '|') {
/* >|FILE redirect ("clobbering" >).
* Since we do not support "set -o noclobber" yet,
* >| and > are the same for now. Just eat |.
*/
ch = i_getch(input);
nommu_addchr(&ctx->as_string, ch);
}
}
/* Create a new redir_struct and append it to the linked list */
redirp = &command->redirects;
while ((redir = *redirp) != NULL) {
redirp = &(redir->next);
}
*redirp = redir = xzalloc(sizeof(*redir));
/* redir->next = NULL; */
/* redir->rd_filename = NULL; */
redir->rd_type = style;
redir->rd_fd = (fd == -1) ? redir_table[style].default_fd : fd;
debug_printf_parse("redirect type %d %s\n", redir->rd_fd,
redir_table[style].descrip);
redir->rd_dup = dup_num;
if (style != REDIRECT_HEREDOC && dup_num != REDIRFD_TO_FILE) {
/* Erik had a check here that the file descriptor in question
* is legit; I postpone that to "run time"
* A "-" representation of "close me" shows up as a -3 here */
debug_printf_parse("duplicating redirect '%d>&%d'\n",
redir->rd_fd, redir->rd_dup);
} else {
/* Set ctx->pending_redirect, so we know what to do at the
* end of the next parsed word. */
ctx->pending_redirect = redir;
}
return 0;
}
/* If a redirect is immediately preceded by a number, that number is
* supposed to tell which file descriptor to redirect. This routine
* looks for such preceding numbers. In an ideal world this routine
* needs to handle all the following classes of redirects...
* echo 2>foo # redirects fd 2 to file "foo", nothing passed to echo
* echo 49>foo # redirects fd 49 to file "foo", nothing passed to echo
* echo -2>foo # redirects fd 1 to file "foo", "-2" passed to echo
* echo 49x>foo # redirects fd 1 to file "foo", "49x" passed to echo
*
* http://www.opengroup.org/onlinepubs/009695399/utilities/xcu_chap02.html
* "2.7 Redirection
* ... If n is quoted, the number shall not be recognized as part of
* the redirection expression. For example:
* echo \2>a
* writes the character 2 into file a"
* We are getting it right by setting ->o_quoted on any \<char>
*
* A -1 return means no valid number was found,
* the caller should use the appropriate default for this redirection.
*/
static int redirect_opt_num(o_string *o)
{
int num;
if (o->data == NULL)
return -1;
num = bb_strtou(o->data, NULL, 10);
if (errno || num < 0)
return -1;
o_reset_to_empty_unquoted(o);
return num;
}
#if BB_MMU
#define fetch_till_str(as_string, input, word, skip_tabs) \
fetch_till_str(input, word, skip_tabs)
#endif
static char *fetch_till_str(o_string *as_string,
struct in_str *input,
const char *word,
int skip_tabs)
{
o_string heredoc = NULL_O_STRING;
int past_EOL = 0;
int ch;
goto jump_in;
while (1) {
ch = i_getch(input);
nommu_addchr(as_string, ch);
if (ch == '\n') {
if (strcmp(heredoc.data + past_EOL, word) == 0) {
heredoc.data[past_EOL] = '\0';
debug_printf_parse("parsed heredoc '%s'\n", heredoc.data);
return heredoc.data;
}
do {
o_addchr(&heredoc, ch);
past_EOL = heredoc.length;
jump_in:
do {
ch = i_getch(input);
nommu_addchr(as_string, ch);
} while (skip_tabs && ch == '\t');
} while (ch == '\n');
}
if (ch == EOF) {
o_free_unsafe(&heredoc);
return NULL;
}
o_addchr(&heredoc, ch);
nommu_addchr(as_string, ch);
}
}
/* Look at entire parse tree for not-yet-loaded REDIRECT_HEREDOCs
* and load them all. There should be exactly heredoc_cnt of them.
*/
static int fetch_heredocs(int heredoc_cnt, struct parse_context *ctx, struct in_str *input)
{
struct pipe *pi = ctx->list_head;
while (pi && heredoc_cnt) {
int i;
struct command *cmd = pi->cmds;
debug_printf_parse("fetch_heredocs: num_cmds:%d cmd argv0:'%s'\n",
pi->num_cmds,
cmd->argv ? cmd->argv[0] : "NONE");
for (i = 0; i < pi->num_cmds; i++) {
struct redir_struct *redir = cmd->redirects;
debug_printf_parse("fetch_heredocs: %d cmd argv0:'%s'\n",
i, cmd->argv ? cmd->argv[0] : "NONE");
while (redir) {
if (redir->rd_type == REDIRECT_HEREDOC) {
char *p;
redir->rd_type = REDIRECT_HEREDOC2;
/* redir->dup is (ab)used to indicate <<- */
p = fetch_till_str(&ctx->as_string, input,
redir->rd_filename, redir->rd_dup & HEREDOC_SKIPTABS);
if (!p) {
syntax_error("unexpected EOF in here document");
return 1;
}
free(redir->rd_filename);
redir->rd_filename = p;
heredoc_cnt--;
}
redir = redir->next;
}
cmd++;
}
pi = pi->next;
}
#if 0
/* Should be 0. If it isn't, it's a parse error */
if (heredoc_cnt)
bb_error_msg_and_die("heredoc BUG 2");
#endif
return 0;
}
#if ENABLE_HUSH_TICK
static FILE *generate_stream_from_string(const char *s)
{
FILE *pf;
int pid, channel[2];
#if !BB_MMU
char **to_free;
#endif
xpipe(channel);
pid = BB_MMU ? fork() : vfork();
if (pid < 0)
bb_perror_msg_and_die(BB_MMU ? "fork" : "vfork");
if (pid == 0) { /* child */
disable_restore_tty_pgrp_on_exit();
/* Process substitution is not considered to be usual
* 'command execution'.
* SUSv3 says ctrl-Z should be ignored, ctrl-C should not.
*/
bb_signals(0
+ (1 << SIGTSTP)
+ (1 << SIGTTIN)
+ (1 << SIGTTOU)
, SIG_IGN);
close(channel[0]); /* NB: close _first_, then move fd! */
xmove_fd(channel[1], 1);
/* Prevent it from trying to handle ctrl-z etc */
USE_HUSH_JOB(G.run_list_level = 1;)
#if BB_MMU
reset_traps_to_defaults();
parse_and_run_string(s);
_exit(G.last_exitcode);
#else
/* We re-execute after vfork on NOMMU. This makes this script safe:
* yes "0123456789012345678901234567890" | dd bs=32 count=64k >BIG
* huge=`cat BIG` # was blocking here forever
* echo OK
*/
re_execute_shell(&to_free,
s,
G.global_argv[0],
G.global_argv + 1);
#endif
}
/* parent */
enable_restore_tty_pgrp_on_exit();
#if !BB_MMU
free(to_free);
#endif
close(channel[1]);
pf = fdopen(channel[0], "r");
return pf;
}
/* Return code is exit status of the process that is run. */
static int process_command_subs(o_string *dest, const char *s)
{
FILE *pf;
struct in_str pipe_str;
int ch, eol_cnt;
pf = generate_stream_from_string(s);
if (pf == NULL)
return 1;
close_on_exec_on(fileno(pf));
/* Now send results of command back into original context */
setup_file_in_str(&pipe_str, pf);
eol_cnt = 0;
while ((ch = i_getch(&pipe_str)) != EOF) {
if (ch == '\n') {
eol_cnt++;
continue;
}
while (eol_cnt) {
o_addchr(dest, '\n');
eol_cnt--;
}
o_addQchr(dest, ch);
}
debug_printf("done reading from pipe, pclose()ing\n");
/* Note: we got EOF, and we just close the read end of the pipe.
* We do not wait for the `cmd` child to terminate. bash and ash do.
* Try these:
* echo `echo Hi; exec 1>&-; sleep 2` - bash waits 2 sec
* `false`; echo $? - bash outputs "1"
*/
fclose(pf);
debug_printf("closed FILE from child. return 0\n");
return 0;
}
#endif
static int parse_group(o_string *dest, struct parse_context *ctx,
struct in_str *input, int ch)
{
/* dest contains characters seen prior to ( or {.
* Typically it's empty, but for function defs,
* it contains function name (without '()'). */
struct pipe *pipe_list;
int endch;
struct command *command = ctx->command;
debug_printf_parse("parse_group entered\n");
#if ENABLE_HUSH_FUNCTIONS
if (ch == '(' && !dest->o_quoted) {
if (dest->length)
done_word(dest, ctx);
if (!command->argv)
goto skip; /* (... */
if (command->argv[1]) { /* word word ... (... */
syntax_error_unexpected_ch('(');
return 1;
}
/* it is "word(..." or "word (..." */
do
ch = i_getch(input);
while (ch == ' ' || ch == '\t');
if (ch != ')') {
syntax_error_unexpected_ch(ch);
return 1;
}
nommu_addchr(&ctx->as_string, ch);
do
ch = i_getch(input);
while (ch == ' ' || ch == '\t' || ch == '\n');
if (ch != '{') {
syntax_error_unexpected_ch(ch);
return 1;
}
nommu_addchr(&ctx->as_string, ch);
command->grp_type = GRP_FUNCTION;
goto skip;
}
#endif
if (command->argv /* word [word]{... */
|| dest->length /* word{... */
|| dest->o_quoted /* ""{... */
) {
syntax_error(NULL);
debug_printf_parse("parse_group return 1: "
"syntax error, groups and arglists don't mix\n");
return 1;
}
#if ENABLE_HUSH_FUNCTIONS
skip:
#endif
endch = '}';
if (ch == '(') {
endch = ')';
command->grp_type = GRP_SUBSHELL;
}
{
#if !BB_MMU
char *as_string = NULL;
#endif
pipe_list = parse_stream(&as_string, input, endch);
#if !BB_MMU
if (as_string)
o_addstr(&ctx->as_string, as_string);
#endif
/* empty ()/{} or parse error? */
if (!pipe_list || pipe_list == ERR_PTR) {
#if !BB_MMU
free(as_string);
#endif
syntax_error(NULL);
debug_printf_parse("parse_group return 1: "
"parse_stream returned %p\n", pipe_list);
return 1;
}
command->group = pipe_list;
#if !BB_MMU
as_string[strlen(as_string) - 1] = '\0'; /* plink ')' or '}' */
command->group_as_string = as_string;
debug_printf_parse("end of group, remembering as:'%s'\n",
command->group_as_string);
#endif
}
debug_printf_parse("parse_group return 0\n");
return 0;
/* command remains "open", available for possible redirects */
}
#if ENABLE_HUSH_TICK || ENABLE_SH_MATH_SUPPORT
/* Subroutines for copying $(...) and `...` things */
static void add_till_backquote(o_string *dest, struct in_str *input);
/* '...' */
static void add_till_single_quote(o_string *dest, struct in_str *input)
{
while (1) {
int ch = i_getch(input);
if (ch == EOF) {
syntax_error_unterm_ch('\'');
/*xfunc_die(); - redundant */
}
if (ch == '\'')
return;
o_addchr(dest, ch);
}
}
/* "...\"...`..`...." - do we need to handle "...$(..)..." too? */
static void add_till_double_quote(o_string *dest, struct in_str *input)
{
while (1) {
int ch = i_getch(input);
if (ch == EOF) {
syntax_error_unterm_ch('"');
/*xfunc_die(); - redundant */
}
if (ch == '"')
return;
if (ch == '\\') { /* \x. Copy both chars. */
o_addchr(dest, ch);
ch = i_getch(input);
}
o_addchr(dest, ch);
if (ch == '`') {
add_till_backquote(dest, input);
o_addchr(dest, ch);
continue;
}
//if (ch == '$') ...
}
}
/* Process `cmd` - copy contents until "`" is seen. Complicated by
* \` quoting.
* "Within the backquoted style of command substitution, backslash
* shall retain its literal meaning, except when followed by: '$', '`', or '\'.
* The search for the matching backquote shall be satisfied by the first
* backquote found without a preceding backslash; during this search,
* if a non-escaped backquote is encountered within a shell comment,
* a here-document, an embedded command substitution of the $(command)
* form, or a quoted string, undefined results occur. A single-quoted
* or double-quoted string that begins, but does not end, within the
* "`...`" sequence produces undefined results."
* Example Output
* echo `echo '\'TEST\`echo ZZ\`BEST` \TESTZZBEST
*/
static void add_till_backquote(o_string *dest, struct in_str *input)
{
while (1) {
int ch = i_getch(input);
if (ch == EOF) {
syntax_error_unterm_ch('`');
/*xfunc_die(); - redundant */
}
if (ch == '`')
return;
if (ch == '\\') {
/* \x. Copy both chars unless it is \` */
int ch2 = i_getch(input);
if (ch2 == EOF) {
syntax_error_unterm_ch('`');
/*xfunc_die(); - redundant */
}
if (ch2 != '`' && ch2 != '$' && ch2 != '\\')
o_addchr(dest, ch);
ch = ch2;
}
o_addchr(dest, ch);
}
}
/* Process $(cmd) - copy contents until ")" is seen. Complicated by
* quoting and nested ()s.
* "With the $(command) style of command substitution, all characters
* following the open parenthesis to the matching closing parenthesis
* constitute the command. Any valid shell script can be used for command,
* except a script consisting solely of redirections which produces
* unspecified results."
* Example Output
* echo $(echo '(TEST)' BEST) (TEST) BEST
* echo $(echo 'TEST)' BEST) TEST) BEST
* echo $(echo \(\(TEST\) BEST) ((TEST) BEST
*/
static void add_till_closing_paren(o_string *dest, struct in_str *input, bool dbl)
{
int count = 0;
while (1) {
int ch = i_getch(input);
if (ch == EOF) {
syntax_error_unterm_ch(')');
/*xfunc_die(); - redundant */
}
if (ch == '(')
count++;
if (ch == ')') {
if (--count < 0) {
if (!dbl)
break;
if (i_peek(input) == ')') {
i_getch(input);
break;
}
}
}
o_addchr(dest, ch);
if (ch == '\'') {
add_till_single_quote(dest, input);
o_addchr(dest, ch);
continue;
}
if (ch == '"') {
add_till_double_quote(dest, input);
o_addchr(dest, ch);
continue;
}
if (ch == '\\') {
/* \x. Copy verbatim. Important for \(, \) */
ch = i_getch(input);
if (ch == EOF) {
syntax_error_unterm_ch(')');
/*xfunc_die(); - redundant */
}
o_addchr(dest, ch);
continue;
}
}
}
#endif /* ENABLE_HUSH_TICK || ENABLE_SH_MATH_SUPPORT */
/* Return code: 0 for OK, 1 for syntax error */
#if BB_MMU
#define handle_dollar(as_string, dest, input) \
handle_dollar(dest, input)
#endif
static int handle_dollar(o_string *as_string,
o_string *dest,
struct in_str *input)
{
int expansion;
int ch = i_peek(input); /* first character after the $ */
unsigned char quote_mask = dest->o_escape ? 0x80 : 0;
debug_printf_parse("handle_dollar entered: ch='%c'\n", ch);
if (isalpha(ch)) {
ch = i_getch(input);
nommu_addchr(as_string, ch);
make_var:
o_addchr(dest, SPECIAL_VAR_SYMBOL);
while (1) {
debug_printf_parse(": '%c'\n", ch);
o_addchr(dest, ch | quote_mask);
quote_mask = 0;
ch = i_peek(input);
if (!isalnum(ch) && ch != '_')
break;
ch = i_getch(input);
nommu_addchr(as_string, ch);
}
o_addchr(dest, SPECIAL_VAR_SYMBOL);
} else if (isdigit(ch)) {
make_one_char_var:
ch = i_getch(input);
nommu_addchr(as_string, ch);
o_addchr(dest, SPECIAL_VAR_SYMBOL);
debug_printf_parse(": '%c'\n", ch);
o_addchr(dest, ch | quote_mask);
o_addchr(dest, SPECIAL_VAR_SYMBOL);
} else switch (ch) {
case '$': /* pid */
case '!': /* last bg pid */
case '?': /* last exit code */
case '#': /* number of args */
case '*': /* args */
case '@': /* args */
goto make_one_char_var;
case '{': {
bool first_char, all_digits;
o_addchr(dest, SPECIAL_VAR_SYMBOL);
ch = i_getch(input);
nommu_addchr(as_string, ch);
/* XXX maybe someone will try to escape the '}' */
expansion = 0;
first_char = true;
all_digits = false;
while (1) {
ch = i_getch(input);
nommu_addchr(as_string, ch);
if (ch == '}')
break;
if (first_char) {
if (ch == '#')
/* ${#var}: length of var contents */
goto char_ok;
else if (isdigit(ch)) {
all_digits = true;
goto char_ok;
}
}
if (expansion < 2
&& ( (all_digits && !isdigit(ch))
|| (!all_digits && !isalnum(ch) && ch != '_')
)
) {
/* handle parameter expansions
* http://www.opengroup.org/onlinepubs/009695399/utilities/xcu_chap02.html#tag_02_06_02
*/
if (first_char)
goto case_default;
switch (ch) {
case ':': /* null modifier */
if (expansion == 0) {
debug_printf_parse(": null modifier\n");
++expansion;
break;
}
goto case_default;
case '#': /* remove prefix */
case '%': /* remove suffix */
if (expansion == 0) {
debug_printf_parse(": remove suffix/prefix\n");
expansion = 2;
break;
}
goto case_default;
case '-': /* default value */
case '=': /* assign default */
case '+': /* alternative */
case '?': /* error indicate */
debug_printf_parse(": parameter expansion\n");
expansion = 2;
break;
default:
case_default:
syntax_error_unterm_str("${name}");
debug_printf_parse("handle_dollar return 1: unterminated ${name}\n");
return 1;
}
}
char_ok:
debug_printf_parse(": '%c'\n", ch);
o_addchr(dest, ch | quote_mask);
quote_mask = 0;
first_char = false;
}
o_addchr(dest, SPECIAL_VAR_SYMBOL);
break;
}
#if (ENABLE_SH_MATH_SUPPORT || ENABLE_HUSH_TICK)
case '(': {
# if !BB_MMU
int pos;
# endif
ch = i_getch(input);
nommu_addchr(as_string, ch);
# if ENABLE_SH_MATH_SUPPORT
if (i_peek(input) == '(') {
ch = i_getch(input);
nommu_addchr(as_string, ch);
o_addchr(dest, SPECIAL_VAR_SYMBOL);
o_addchr(dest, /*quote_mask |*/ '+');
# if !BB_MMU
pos = dest->length;
# endif
add_till_closing_paren(dest, input, true);
# if !BB_MMU
if (as_string) {
o_addstr(as_string, dest->data + pos);
o_addchr(as_string, ')');
o_addchr(as_string, ')');
}
# endif
o_addchr(dest, SPECIAL_VAR_SYMBOL);
break;
}
# endif
# if ENABLE_HUSH_TICK
o_addchr(dest, SPECIAL_VAR_SYMBOL);
o_addchr(dest, quote_mask | '`');
# if !BB_MMU
pos = dest->length;
# endif
add_till_closing_paren(dest, input, false);
# if !BB_MMU
if (as_string) {
o_addstr(as_string, dest->data + pos);
o_addchr(as_string, '`');
}
# endif
o_addchr(dest, SPECIAL_VAR_SYMBOL);
# endif
break;
}
#endif
case '_':
ch = i_getch(input);
nommu_addchr(as_string, ch);
ch = i_peek(input);
if (isalnum(ch)) { /* it's $_name or $_123 */
ch = '_';
goto make_var;
}
/* else: it's $_ */
/* TODO: */
/* $_ Shell or shell script name; or last cmd name */
/* $- Option flags set by set builtin or shell options (-i etc) */
default:
o_addQchr(dest, '$');
}
debug_printf_parse("handle_dollar return 0\n");
return 0;
}
#if BB_MMU
#define parse_stream_dquoted(as_string, dest, input, dquote_end) \
parse_stream_dquoted(dest, input, dquote_end)
#endif
static int parse_stream_dquoted(o_string *as_string,
o_string *dest,
struct in_str *input,
int dquote_end)
{
int ch;
int next;
again:
ch = i_getch(input);
if (ch != EOF)
nommu_addchr(as_string, ch);
if (ch == dquote_end) { /* may be only '"' or EOF */
if (dest->o_assignment == NOT_ASSIGNMENT)
dest->o_escape ^= 1;
debug_printf_parse("parse_stream_dquoted return 0\n");
return 0;
}
/* note: can't move it above ch == dquote_end check! */
if (ch == EOF) {
syntax_error_unterm_ch('"');
/*xfunc_die(); - redundant */
}
next = '\0';
if (ch != '\n') {
next = i_peek(input);
}
debug_printf_parse(": ch=%c (%d) escape=%d\n",
ch, ch, dest->o_escape);
if (ch == '\\') {
if (next == EOF) {
syntax_error("\\<eof>");
xfunc_die();
}
/* bash:
* "The backslash retains its special meaning [in "..."]
* only when followed by one of the following characters:
* $, `, ", \, or <newline>. A double quote may be quoted
* within double quotes by preceding it with a backslash.
*/
if (strchr("$`\"\\", next) != NULL) {
o_addqchr(dest, i_getch(input));
} else {
o_addqchr(dest, '\\');
}
goto again;
}
if (ch == '$') {
if (handle_dollar(as_string, dest, input) != 0) {
debug_printf_parse("parse_stream_dquoted return 1: "
"handle_dollar returned non-0\n");
return 1;
}
goto again;
}
#if ENABLE_HUSH_TICK
if (ch == '`') {
//int pos = dest->length;
o_addchr(dest, SPECIAL_VAR_SYMBOL);
o_addchr(dest, 0x80 | '`');
add_till_backquote(dest, input);
o_addchr(dest, SPECIAL_VAR_SYMBOL);
//debug_printf_subst("SUBST RES3 '%s'\n", dest->data + pos);
goto again;
}
#endif
o_addQchr(dest, ch);
if (ch == '='
&& (dest->o_assignment == MAYBE_ASSIGNMENT
|| dest->o_assignment == WORD_IS_KEYWORD)
&& is_well_formed_var_name(dest->data, '=')
) {
dest->o_assignment = DEFINITELY_ASSIGNMENT;
}
goto again;
}
/*
* Scan input until EOF or end_trigger char.
* Return a list of pipes to execute, or NULL on EOF
* or if end_trigger character is met.
* On syntax error, exit is shell is not interactive,
* reset parsing machinery and start parsing anew,
* or return ERR_PTR.
*/
static struct pipe *parse_stream(char **pstring,
struct in_str *input,
int end_trigger)
{
struct parse_context ctx;
o_string dest = NULL_O_STRING;
int is_in_dquote;
int heredoc_cnt;
/* Double-quote state is handled in the state variable is_in_dquote.
* A single-quote triggers a bypass of the main loop until its mate is
* found. When recursing, quote state is passed in via dest->o_escape.
*/
debug_printf_parse("parse_stream entered, end_trigger='%c'\n",
end_trigger ? : 'X');
debug_enter();
G.ifs = get_local_var_value("IFS");
if (G.ifs == NULL)
G.ifs = " \t\n";
reset:
#if ENABLE_HUSH_INTERACTIVE
input->promptmode = 0; /* PS1 */
#endif
/* dest.o_assignment = MAYBE_ASSIGNMENT; - already is */
initialize_context(&ctx);
is_in_dquote = 0;
heredoc_cnt = 0;
while (1) {
const char *is_ifs;
const char *is_special;
int ch;
int next;
int redir_fd;
redir_type redir_style;
if (is_in_dquote) {
/* dest.o_quoted = 1; - already is (see below) */
if (parse_stream_dquoted(&ctx.as_string, &dest, input, '"')) {
goto parse_error;
}
/* We reached closing '"' */
is_in_dquote = 0;
}
ch = i_getch(input);
debug_printf_parse(": ch=%c (%d) escape=%d\n",
ch, ch, dest.o_escape);
if (ch == EOF) {
struct pipe *pi;
if (heredoc_cnt) {
syntax_error_unterm_str("here document");
xfunc_die();
}
if (done_word(&dest, &ctx)) {
xfunc_die();
}
o_free(&dest);
done_pipe(&ctx, PIPE_SEQ);
pi = ctx.list_head;
/* If we got nothing... */
/* (this makes bare "&" cmd a no-op.
* bash says: "syntax error near unexpected token '&'") */
if (pi->num_cmds == 0
IF_HAS_KEYWORDS( && pi->res_word == RES_NONE)
) {
free_pipe_list(pi);
pi = NULL;
}
#if !BB_MMU
debug_printf_parse("as_string '%s'\n", ctx.as_string.data);
if (pstring)
*pstring = ctx.as_string.data;
else
o_free_unsafe(&ctx.as_string);
#endif
debug_leave();
debug_printf_parse("parse_stream return %p\n", pi);
return pi;
}
nommu_addchr(&ctx.as_string, ch);
is_ifs = strchr(G.ifs, ch);
is_special = strchr("<>;&|(){}#'" /* special outside of "str" */
"\\$\"" USE_HUSH_TICK("`") /* always special */
, ch);
if (!is_special && !is_ifs) { /* ordinary char */
o_addQchr(&dest, ch);
if ((dest.o_assignment == MAYBE_ASSIGNMENT
|| dest.o_assignment == WORD_IS_KEYWORD)
&& ch == '='
&& is_well_formed_var_name(dest.data, '=')
) {
dest.o_assignment = DEFINITELY_ASSIGNMENT;
}
continue;
}
if (is_ifs) {
if (done_word(&dest, &ctx)) {
goto parse_error;
}
if (ch == '\n') {
#if ENABLE_HUSH_CASE
/* "case ... in <newline> word) ..." -
* newlines are ignored (but ';' wouldn't be) */
if (ctx.command->argv == NULL
&& ctx.ctx_res_w == RES_MATCH
) {
continue;
}
#endif
/* Treat newline as a command separator. */
done_pipe(&ctx, PIPE_SEQ);
debug_printf_parse("heredoc_cnt:%d\n", heredoc_cnt);
if (heredoc_cnt) {
if (fetch_heredocs(heredoc_cnt, &ctx, input)) {
goto parse_error;
}
heredoc_cnt = 0;
}
dest.o_assignment = MAYBE_ASSIGNMENT;
ch = ';';
/* note: if (is_ifs) continue;
* will still trigger for us */
}
}
if (end_trigger && end_trigger == ch
&& (heredoc_cnt == 0 || end_trigger != ';')
) {
//TODO: disallow "{ cmd }" without semicolon
if (heredoc_cnt) {
/* This is technically valid:
* { cat <<HERE; }; echo Ok
* heredoc
* heredoc
* heredoc
* HERE
* but we don't support this.
* We require heredoc to be in enclosing {}/(),
* if any.
*/
syntax_error_unterm_str("here document");
goto parse_error;
}
if (done_word(&dest, &ctx)) {
goto parse_error;
}
done_pipe(&ctx, PIPE_SEQ);
dest.o_assignment = MAYBE_ASSIGNMENT;
/* Do we sit outside of any if's, loops or case's? */
if (!HAS_KEYWORDS
IF_HAS_KEYWORDS(|| (ctx.ctx_res_w == RES_NONE && ctx.old_flag == 0))
) {
o_free(&dest);
#if !BB_MMU
debug_printf_parse("as_string '%s'\n", ctx.as_string.data);
if (pstring)
*pstring = ctx.as_string.data;
else
o_free_unsafe(&ctx.as_string);
#endif
debug_leave();
debug_printf_parse("parse_stream return %p: "
"end_trigger char found\n",
ctx.list_head);
return ctx.list_head;
}
}
if (is_ifs)
continue;
next = '\0';
if (ch != '\n') {
next = i_peek(input);
}
/* Catch <, > before deciding whether this word is
* an assignment. a=1 2>z b=2: b=2 is still assignment */
switch (ch) {
case '>':
redir_fd = redirect_opt_num(&dest);
if (done_word(&dest, &ctx)) {
goto parse_error;
}
redir_style = REDIRECT_OVERWRITE;
if (next == '>') {
redir_style = REDIRECT_APPEND;
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
}
#if 0
else if (next == '(') {
syntax_error(">(process) not supported");
goto parse_error;
}
#endif
if (parse_redirect(&ctx, redir_fd, redir_style, input))
goto parse_error;
continue; /* back to top of while (1) */
case '<':
redir_fd = redirect_opt_num(&dest);
if (done_word(&dest, &ctx)) {
goto parse_error;
}
redir_style = REDIRECT_INPUT;
if (next == '<') {
redir_style = REDIRECT_HEREDOC;
heredoc_cnt++;
debug_printf_parse("++heredoc_cnt=%d\n", heredoc_cnt);
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
} else if (next == '>') {
redir_style = REDIRECT_IO;
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
}
#if 0
else if (next == '(') {
syntax_error("<(process) not supported");
goto parse_error;
}
#endif
if (parse_redirect(&ctx, redir_fd, redir_style, input))
goto parse_error;
continue; /* back to top of while (1) */
}
if (dest.o_assignment == MAYBE_ASSIGNMENT
/* check that we are not in word in "a=1 2>word b=1": */
&& !ctx.pending_redirect
) {
/* ch is a special char and thus this word
* cannot be an assignment */
dest.o_assignment = NOT_ASSIGNMENT;
}
switch (ch) {
case '#':
if (dest.length == 0) {
while (1) {
ch = i_peek(input);
if (ch == EOF || ch == '\n')
break;
i_getch(input);
/* note: we do not add it to &ctx.as_string */
}
nommu_addchr(&ctx.as_string, '\n');
} else {
o_addQchr(&dest, ch);
}
break;
case '\\':
if (next == EOF) {
syntax_error("\\<eof>");
xfunc_die();
}
o_addchr(&dest, '\\');
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
o_addchr(&dest, ch);
/* Example: echo Hello \2>file
* we need to know that word 2 is quoted */
dest.o_quoted = 1;
break;
case '$':
if (handle_dollar(&ctx.as_string, &dest, input) != 0) {
debug_printf_parse("parse_stream parse error: "
"handle_dollar returned non-0\n");
goto parse_error;
}
break;
case '\'':
dest.o_quoted = 1;
while (1) {
ch = i_getch(input);
if (ch == EOF) {
syntax_error_unterm_ch('\'');
/*xfunc_die(); - redundant */
}
nommu_addchr(&ctx.as_string, ch);
if (ch == '\'')
break;
if (dest.o_assignment == NOT_ASSIGNMENT)
o_addqchr(&dest, ch);
else
o_addchr(&dest, ch);
}
break;
case '"':
dest.o_quoted = 1;
is_in_dquote ^= 1; /* invert */
if (dest.o_assignment == NOT_ASSIGNMENT)
dest.o_escape ^= 1;
break;
#if ENABLE_HUSH_TICK
case '`': {
#if !BB_MMU
int pos;
#endif
o_addchr(&dest, SPECIAL_VAR_SYMBOL);
o_addchr(&dest, '`');
#if !BB_MMU
pos = dest.length;
#endif
add_till_backquote(&dest, input);
#if !BB_MMU
o_addstr(&ctx.as_string, dest.data + pos);
o_addchr(&ctx.as_string, '`');
#endif
o_addchr(&dest, SPECIAL_VAR_SYMBOL);
//debug_printf_subst("SUBST RES3 '%s'\n", dest.data + pos);
break;
}
#endif
case ';':
#if ENABLE_HUSH_CASE
case_semi:
#endif
if (done_word(&dest, &ctx)) {
goto parse_error;
}
done_pipe(&ctx, PIPE_SEQ);
#if ENABLE_HUSH_CASE
/* Eat multiple semicolons, detect
* whether it means something special */
while (1) {
ch = i_peek(input);
if (ch != ';')
break;
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
if (ctx.ctx_res_w == RES_CASEI) {
ctx.ctx_dsemicolon = 1;
ctx.ctx_res_w = RES_MATCH;
break;
}
}
#endif
new_cmd:
/* We just finished a cmd. New one may start
* with an assignment */
dest.o_assignment = MAYBE_ASSIGNMENT;
break;
case '&':
if (done_word(&dest, &ctx)) {
goto parse_error;
}
if (next == '&') {
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
done_pipe(&ctx, PIPE_AND);
} else {
done_pipe(&ctx, PIPE_BG);
}
goto new_cmd;
case '|':
if (done_word(&dest, &ctx)) {
goto parse_error;
}
#if ENABLE_HUSH_CASE
if (ctx.ctx_res_w == RES_MATCH)
break; /* we are in case's "word | word)" */
#endif
if (next == '|') { /* || */
ch = i_getch(input);
nommu_addchr(&ctx.as_string, ch);
done_pipe(&ctx, PIPE_OR);
} else {
/* we could pick up a file descriptor choice here
* with redirect_opt_num(), but bash doesn't do it.
* "echo foo 2| cat" yields "foo 2". */
done_command(&ctx);
}
goto new_cmd;
case '(':
#if ENABLE_HUSH_CASE
/* "case... in [(]word)..." - skip '(' */
if (ctx.ctx_res_w == RES_MATCH
&& ctx.command->argv == NULL /* not (word|(... */
&& dest.length == 0 /* not word(... */
&& dest.o_quoted == 0 /* not ""(... */
) {
continue;
}
#endif
case '{':
if (parse_group(&dest, &ctx, input, ch) != 0) {
goto parse_error;
}
goto new_cmd;
case ')':
#if ENABLE_HUSH_CASE
if (ctx.ctx_res_w == RES_MATCH)
goto case_semi;
#endif
case '}':
/* proper use of this character is caught by end_trigger:
* if we see {, we call parse_group(..., end_trigger='}')
* and it will match } earlier (not here). */
syntax_error_unexpected_ch(ch);
goto parse_error;
default:
if (HUSH_DEBUG)
bb_error_msg_and_die("BUG: unexpected %c\n", ch);
}
} /* while (1) */
parse_error:
{
struct parse_context *pctx;
IF_HAS_KEYWORDS(struct parse_context *p2;)
/* Clean up allocated tree.
* Samples for finding leaks on syntax error recovery path.
* Run them from interactive shell, watch pmap `pidof hush`.
* while if false; then false; fi do break; done
* (bash accepts it)
* while if false; then false; fi; do break; fi
* Samples to catch leaks at execution:
* while if (true | {true;}); then echo ok; fi; do break; done
* while if (true | {true;}); then echo ok; fi; do (if echo ok; break; then :; fi) | cat; break; done
*/
pctx = &ctx;
do {
/* Update pipe/command counts,
* otherwise freeing may miss some */
done_pipe(pctx, PIPE_SEQ);
debug_printf_clean("freeing list %p from ctx %p\n",
pctx->list_head, pctx);
debug_print_tree(pctx->list_head, 0);
free_pipe_list(pctx->list_head);
debug_printf_clean("freed list %p\n", pctx->list_head);
#if !BB_MMU
o_free_unsafe(&pctx->as_string);
#endif
IF_HAS_KEYWORDS(p2 = pctx->stack;)
if (pctx != &ctx) {
free(pctx);
}
IF_HAS_KEYWORDS(pctx = p2;)
} while (HAS_KEYWORDS && pctx);
/* Free text, clear all dest fields */
o_free(&dest);
/* If we are not in top-level parse, we return,
* our caller will propagate error.
*/
if (end_trigger != ';') {
#if !BB_MMU
if (pstring)
*pstring = NULL;
#endif
debug_leave();
return ERR_PTR;
}
/* Discard cached input, force prompt */
input->p = NULL;
USE_HUSH_INTERACTIVE(input->promptme = 1;)
goto reset;
}
}
/* Executing from string: eval, sh -c '...'
* or from file: /etc/profile, . file, sh <script>, sh (intereactive)
* end_trigger controls how often we stop parsing
* NUL: parse all, execute, return
* ';': parse till ';' or newline, execute, repeat till EOF
*/
static void parse_and_run_stream(struct in_str *inp, int end_trigger)
{
while (1) {
struct pipe *pipe_list;
pipe_list = parse_stream(NULL, inp, end_trigger);
if (!pipe_list) /* EOF */
break;
debug_print_tree(pipe_list, 0);
debug_printf_exec("parse_and_run_stream: run_and_free_list\n");
run_and_free_list(pipe_list);
}
}
static void parse_and_run_string(const char *s)
{
struct in_str input;
setup_string_in_str(&input, s);
parse_and_run_stream(&input, '\0');
}
static void parse_and_run_file(FILE *f)
{
struct in_str input;
setup_file_in_str(&input, f);
parse_and_run_stream(&input, ';');
}
/* Called a few times only (or even once if "sh -c") */
static void block_signals(int second_time)
{
unsigned sig;
unsigned mask;
mask = (1 << SIGQUIT);
if (G_interactive_fd) {
mask = 0
| (1 << SIGQUIT)
| (1 << SIGTERM)
//TODO | (1 << SIGHUP)
#if ENABLE_HUSH_JOB
| (1 << SIGTTIN) | (1 << SIGTTOU) | (1 << SIGTSTP)
#endif
| (1 << SIGINT)
;
}
G.non_DFL_mask = mask;
if (!second_time)
sigprocmask(SIG_SETMASK, NULL, &G.blocked_set);
sig = 0;
while (mask) {
if (mask & 1)
sigaddset(&G.blocked_set, sig);
mask >>= 1;
sig++;
}
sigdelset(&G.blocked_set, SIGCHLD);
sigprocmask(SIG_SETMASK, &G.blocked_set,
second_time ? NULL : &G.inherited_set);
/* POSIX allows shell to re-enable SIGCHLD
* even if it was SIG_IGN on entry */
// G.count_SIGCHLD++; /* ensure it is != G.handled_SIGCHLD */
if (!second_time)
signal(SIGCHLD, SIG_DFL); // SIGCHLD_handler);
}
#if ENABLE_HUSH_JOB
/* helper */
static void maybe_set_to_sigexit(int sig)
{
void (*handler)(int);
/* non_DFL_mask'ed signals are, well, masked,
* no need to set handler for them.
*/
if (!((G.non_DFL_mask >> sig) & 1)) {
handler = signal(sig, sigexit);
if (handler == SIG_IGN) /* oops... restore back to IGN! */
signal(sig, handler);
}
}
/* Set handlers to restore tty pgrp and exit */
static void set_fatal_handlers(void)
{
/* We _must_ restore tty pgrp on fatal signals */
if (HUSH_DEBUG) {
maybe_set_to_sigexit(SIGILL );
maybe_set_to_sigexit(SIGFPE );
maybe_set_to_sigexit(SIGBUS );
maybe_set_to_sigexit(SIGSEGV);
maybe_set_to_sigexit(SIGTRAP);
} /* else: hush is perfect. what SEGV? */
maybe_set_to_sigexit(SIGABRT);
/* bash 3.2 seems to handle these just like 'fatal' ones */
maybe_set_to_sigexit(SIGPIPE);
maybe_set_to_sigexit(SIGALRM);
//TODO: disable and move down when proper SIGHUP handling is added
maybe_set_to_sigexit(SIGHUP );
/* if we are interactive, [SIGHUP,] SIGTERM and SIGINT are masked.
* if we aren't interactive... but in this case
* we never want to restore pgrp on exit, and this fn is not called */
/*maybe_set_to_sigexit(SIGTERM);*/
/*maybe_set_to_sigexit(SIGINT );*/
}
#endif
static int set_mode(const char cstate, const char mode)
{
int state = (cstate == '-' ? 1 : 0);
switch (mode) {
case 'n': G.fake_mode = state; break;
case 'x': /*G.debug_mode = state;*/ break;
default: return EXIT_FAILURE;
}
return EXIT_SUCCESS;
}
int hush_main(int argc, char **argv) MAIN_EXTERNALLY_VISIBLE;
int hush_main(int argc, char **argv)
{
static const struct variable const_shell_ver = {
.next = NULL,
.varstr = (char*)hush_version_str,
.max_len = 1, /* 0 can provoke free(name) */
.flg_export = 1,
.flg_read_only = 1,
};
int signal_mask_is_inited = 0;
int opt;
char **e;
struct variable *cur_var;
INIT_G();
if (EXIT_SUCCESS) /* if EXIT_SUCCESS == 0, is already done */
G.last_exitcode = EXIT_SUCCESS;
#if !BB_MMU
G.argv0_for_re_execing = argv[0];
#endif
/* Deal with HUSH_VERSION */
G.shell_ver = const_shell_ver; /* copying struct here */
G.top_var = &G.shell_ver;
debug_printf_env("unsetenv '%s'\n", "HUSH_VERSION");
unsetenv("HUSH_VERSION"); /* in case it exists in initial env */
/* Initialize our shell local variables with the values
* currently living in the environment */
cur_var = G.top_var;
e = environ;
if (e) while (*e) {
char *value = strchr(*e, '=');
if (value) { /* paranoia */
cur_var->next = xzalloc(sizeof(*cur_var));
cur_var = cur_var->next;
cur_var->varstr = *e;
cur_var->max_len = strlen(*e);
cur_var->flg_export = 1;
}
e++;
}
debug_printf_env("putenv '%s'\n", hush_version_str);
putenv((char *)hush_version_str); /* reinstate HUSH_VERSION */
#if ENABLE_FEATURE_EDITING
G.line_input_state = new_line_input_t(FOR_SHELL);
#endif
G.global_argc = argc;
G.global_argv = argv;
/* Initialize some more globals to non-zero values */
set_cwd();
#if ENABLE_HUSH_INTERACTIVE
if (ENABLE_FEATURE_EDITING)
cmdedit_set_initial_prompt();
G.PS2 = "> ";
#endif
if (setjmp(die_jmp)) {
/* xfunc has failed! die die die */
/* no EXIT traps, this is an escape hatch! */
G.exiting = 1;
hush_exit(xfunc_error_retval);
}
/* Shell is non-interactive at first. We need to call
* block_signals(0) if we are going to execute "sh <script>",
* "sh -c <cmds>" or login shell's /etc/profile and friends.
* If we later decide that we are interactive, we run block_signals(0)
* (or re-run block_signals(1) if we ran block_signals(0) before)
* in order to intercept (more) signals.
*/
/* Parse options */
/* http://www.opengroup.org/onlinepubs/9699919799/utilities/sh.html */
while (1) {
opt = getopt(argc, argv, "c:xins"
#if !BB_MMU
"<:$:R:V:"
# if ENABLE_HUSH_FUNCTIONS
"F:"
# endif
#endif
);
if (opt <= 0)
break;
switch (opt) {
case 'c':
if (!G.root_pid)
G.root_pid = getpid();
G.global_argv = argv + optind;
if (!argv[optind]) {
/* -c 'script' (no params): prevent empty $0 */
*--G.global_argv = argv[0];
optind--;
} /* else -c 'script' PAR0 PAR1: $0 is PAR0 */
G.global_argc = argc - optind;
block_signals(0); /* 0: called 1st time */
parse_and_run_string(optarg);
goto final_return;
case 'i':
/* Well, we cannot just declare interactiveness,
* we have to have some stuff (ctty, etc) */
/* G_interactive_fd++; */
break;
case 's':
/* "-s" means "read from stdin", but this is how we always
* operate, so simply do nothing here. */
break;
#if !BB_MMU
case '<': /* "big heredoc" support */
full_write(STDOUT_FILENO, optarg, strlen(optarg));
_exit(0);
case '$':
G.root_pid = bb_strtou(optarg, &optarg, 16);
optarg++;
G.last_bg_pid = bb_strtou(optarg, &optarg, 16);
optarg++;
G.last_exitcode = bb_strtou(optarg, &optarg, 16);
# if ENABLE_HUSH_LOOPS
optarg++;
G.depth_of_loop = bb_strtou(optarg, &optarg, 16);
# endif
break;
case 'R':
case 'V':
set_local_var(xstrdup(optarg), 0, opt == 'R');
break;
# if ENABLE_HUSH_FUNCTIONS
case 'F': {
struct function *funcp = new_function(optarg);
/* funcp->name is already set to optarg */
/* funcp->body is set to NULL. It's a special case. */
funcp->body_as_string = argv[optind];
optind++;
break;
}
# endif
#endif
case 'n':
case 'x':
if (!set_mode('-', opt))
break;
default:
#ifndef BB_VER
fprintf(stderr, "Usage: sh [FILE]...\n"
" or: sh -c command [args]...\n\n");
exit(EXIT_FAILURE);
#else
bb_show_usage();
#endif
}
} /* option parsing loop */
if (!G.root_pid)
G.root_pid = getpid();
/* If we are login shell... */
if (argv[0] && argv[0][0] == '-') {
FILE *input;
/* XXX what should argv be while sourcing /etc/profile? */
debug_printf("sourcing /etc/profile\n");
input = fopen_for_read("/etc/profile");
if (input != NULL) {
close_on_exec_on(fileno(input));
block_signals(0); /* 0: called 1st time */
signal_mask_is_inited = 1;
parse_and_run_file(input);
fclose(input);
}
/* bash: after sourcing /etc/profile,
* tries to source (in the given order):
* ~/.bash_profile, ~/.bash_login, ~/.profile,
* stopping of first found. --noprofile turns this off.
* bash also sources ~/.bash_logout on exit.
* If called as sh, skips .bash_XXX files.
*/
}
if (argv[optind]) {
FILE *input;
/*
* "bash <script>" (which is never interactive (unless -i?))
* sources $BASH_ENV here (without scanning $PATH).
* If called as sh, does the same but with $ENV.
*/
debug_printf("running script '%s'\n", argv[optind]);
G.global_argv = argv + optind;
G.global_argc = argc - optind;
input = xfopen_for_read(argv[optind]);
close_on_exec_on(fileno(input));
if (!signal_mask_is_inited)
block_signals(0); /* 0: called 1st time */
parse_and_run_file(input);
#if ENABLE_FEATURE_CLEAN_UP
fclose(input);
#endif
goto final_return;
}
/* Up to here, shell was non-interactive. Now it may become one.
* NB: don't forget to (re)run block_signals(0/1) as needed.
*/
/* A shell is interactive if the '-i' flag was given, or if all of
* the following conditions are met:
* no -c command
* no arguments remaining or the -s flag given
* standard input is a terminal
* standard output is a terminal
* Refer to Posix.2, the description of the 'sh' utility.
*/
#if ENABLE_HUSH_JOB
if (isatty(STDIN_FILENO) && isatty(STDOUT_FILENO)) {
G.saved_tty_pgrp = tcgetpgrp(STDIN_FILENO);
debug_printf("saved_tty_pgrp:%d\n", G.saved_tty_pgrp);
//TODO: "interactive" and "have job control" are two different things.
//If tcgetpgrp fails here, "have job control" is false, but "interactive"
//should stay on! Currently, we mix these into one.
if (G.saved_tty_pgrp >= 0) {
/* try to dup stdin to high fd#, >= 255 */
G_interactive_fd = fcntl(STDIN_FILENO, F_DUPFD, 255);
if (G_interactive_fd < 0) {
/* try to dup to any fd */
G_interactive_fd = dup(STDIN_FILENO);
if (G_interactive_fd < 0)
/* give up */
G_interactive_fd = 0;
}
// TODO: track & disallow any attempts of user
// to (inadvertently) close/redirect it
}
}
debug_printf("interactive_fd:%d\n", G_interactive_fd);
if (G_interactive_fd) {
pid_t shell_pgrp;
/* We are indeed interactive shell, and we will perform
* job control. Setting up for that. */
close_on_exec_on(G_interactive_fd);
/* If we were run as 'hush &', sleep until we are
* in the foreground (tty pgrp == our pgrp).
* If we get started under a job aware app (like bash),
* make sure we are now in charge so we don't fight over
* who gets the foreground */
while (1) {
shell_pgrp = getpgrp();
G.saved_tty_pgrp = tcgetpgrp(G_interactive_fd);
if (G.saved_tty_pgrp == shell_pgrp)
break;
/* send TTIN to ourself (should stop us) */
kill(- shell_pgrp, SIGTTIN);
}
/* Block some signals */
block_signals(signal_mask_is_inited);
/* Set other signals to restore saved_tty_pgrp */
set_fatal_handlers();
/* Put ourselves in our own process group */
bb_setpgrp(); /* is the same as setpgid(our_pid, our_pid); */
/* Grab control of the terminal */
tcsetpgrp(G_interactive_fd, getpid());
/* -1 is special - makes xfuncs longjmp, not exit
* (we reset die_sleep = 0 whereever we [v]fork) */
enable_restore_tty_pgrp_on_exit(); /* sets die_sleep = -1 */
} else if (!signal_mask_is_inited) {
block_signals(0); /* 0: called 1st time */
} /* else: block_signals(0) was done before */
#elif ENABLE_HUSH_INTERACTIVE
/* No job control compiled in, only prompt/line editing */
if (isatty(STDIN_FILENO) && isatty(STDOUT_FILENO)) {
G_interactive_fd = fcntl(STDIN_FILENO, F_DUPFD, 255);
if (G_interactive_fd < 0) {
/* try to dup to any fd */
G_interactive_fd = dup(STDIN_FILENO);
if (G_interactive_fd < 0)
/* give up */
G_interactive_fd = 0;
}
}
if (G_interactive_fd) {
close_on_exec_on(G_interactive_fd);
block_signals(signal_mask_is_inited);
} else if (!signal_mask_is_inited) {
block_signals(0);
}
#else
/* We have interactiveness code disabled */
if (!signal_mask_is_inited) {
block_signals(0);
}
#endif
/* bash:
* if interactive but not a login shell, sources ~/.bashrc
* (--norc turns this off, --rcfile <file> overrides)
*/
if (!ENABLE_FEATURE_SH_EXTRA_QUIET && G_interactive_fd) {
printf("\n\n%s hush - the humble shell\n", bb_banner);
printf("Enter 'help' for a list of built-in commands.\n\n");
}
parse_and_run_file(stdin);
final_return:
#if ENABLE_FEATURE_CLEAN_UP
if (G.cwd != bb_msg_unknown)
free((char*)G.cwd);
cur_var = G.top_var->next;
while (cur_var) {
struct variable *tmp = cur_var;
if (!cur_var->max_len)
free(cur_var->varstr);
cur_var = cur_var->next;
free(tmp);
}
#endif
hush_exit(G.last_exitcode);
}
#if ENABLE_LASH
int lash_main(int argc, char **argv) MAIN_EXTERNALLY_VISIBLE;
int lash_main(int argc, char **argv)
{
//bb_error_msg("lash is deprecated, please use hush instead");
return hush_main(argc, argv);
}
#endif
/*
* Built-ins
*/
static int builtin_trap(char **argv)
{
int i;
int sig;
char *new_cmd;
if (!G.traps)
G.traps = xzalloc(sizeof(G.traps[0]) * NSIG);
argv++;
if (!*argv) {
/* No args: print all trapped. This isn't 100% correct as we
* should be escaping the cmd so that it can be pasted back in
*/
for (i = 0; i < NSIG; ++i)
if (G.traps[i])
printf("trap -- '%s' %s\n", G.traps[i], get_signame(i));
return EXIT_SUCCESS;
}
new_cmd = NULL;
i = 0;
/* If first arg is decimal: reset all specified signals */
sig = bb_strtou(*argv, NULL, 10);
if (errno == 0) {
int ret;
set_all:
ret = EXIT_SUCCESS;
while (*argv) {
sig = get_signum(*argv++);
if (sig < 0 || sig >= NSIG) {
ret = EXIT_FAILURE;
/* Mimic bash message exactly */
bb_perror_msg("trap: %s: invalid signal specification", argv[i]);
continue;
}
free(G.traps[sig]);
G.traps[sig] = xstrdup(new_cmd);
debug_printf("trap: setting SIG%s (%i) to '%s'",
get_signame(sig), sig, G.traps[sig]);
/* There is no signal for 0 (EXIT) */
if (sig == 0)
continue;
if (new_cmd) {
sigaddset(&G.blocked_set, sig);
} else {
/* There was a trap handler, we are removing it
* (if sig has non-DFL handling,
* we don't need to do anything) */
if (sig < 32 && (G.non_DFL_mask & (1 << sig)))
continue;
sigdelset(&G.blocked_set, sig);
}
sigprocmask(SIG_SETMASK, &G.blocked_set, NULL);
}
return ret;
}
/* First arg is "-": reset all specified to default */
/* First arg is "": ignore all specified */
/* Everything else: execute first arg upon signal */
if (!argv[1]) {
bb_error_msg("trap: invalid arguments");
return EXIT_FAILURE;
}
if (NOT_LONE_DASH(*argv))
new_cmd = *argv;
argv++;
goto set_all;
}
static int builtin_true(char **argv UNUSED_PARAM)
{
return 0;
}
static int builtin_test(char **argv)
{
int argc = 0;
while (*argv) {
argc++;
argv++;
}
return test_main(argc, argv - argc);
}
static int builtin_echo(char **argv)
{
int argc = 0;
while (*argv) {
argc++;
argv++;
}
return echo_main(argc, argv - argc);
}
static int builtin_eval(char **argv)
{
int rcode = EXIT_SUCCESS;
if (*++argv) {
char *str = expand_strvec_to_string(argv);
/* bash:
* eval "echo Hi; done" ("done" is syntax error):
* "echo Hi" will not execute too.
*/
parse_and_run_string(str);
free(str);
rcode = G.last_exitcode;
}
return rcode;
}
static int builtin_cd(char **argv)
{
const char *newdir = argv[1];
if (newdir == NULL) {
/* bash does nothing (exitcode 0) if HOME is ""; if it's unset,
* bash says "bash: cd: HOME not set" and does nothing
* (exitcode 1)
*/
newdir = getenv("HOME") ? : "/";
}
if (chdir(newdir)) {
/* Mimic bash message exactly */
bb_perror_msg("cd: %s", newdir);
return EXIT_FAILURE;
}
set_cwd();
return EXIT_SUCCESS;
}
static int builtin_exec(char **argv)
{
if (*++argv == NULL)
return EXIT_SUCCESS; /* bash does this */
{
#if !BB_MMU
nommu_save_t dummy;
#endif
// FIXME: if exec fails, bash does NOT exit! We do...
pseudo_exec_argv(&dummy, argv, 0, NULL);
/* never returns */
}
}
static int builtin_exit(char **argv)
{
debug_printf_exec("%s()\n", __func__);
// TODO: bash does it ONLY on top-level sh exit (+interacive only?)
//puts("exit"); /* bash does it */
// TODO: warn if we have background jobs: "There are stopped jobs"
// On second consecutive 'exit', exit anyway.
// perhaps use G.exiting = -1 as indicator "last cmd was exit"
/* note: EXIT trap is run by hush_exit */
if (*++argv == NULL)
hush_exit(G.last_exitcode);
/* mimic bash: exit 123abc == exit 255 + error msg */
xfunc_error_retval = 255;
/* bash: exit -2 == exit 254, no error msg */
hush_exit(xatoi(*argv) & 0xff);
}
static int builtin_export(char **argv)
{
if (*++argv == NULL) {
char **e = environ;
if (e) {
while (*e) {
#if 0
puts(*e++);
#else
/* ash emits: export VAR='VAL'
* bash: declare -x VAR="VAL"
* we follow ash example */
const char *s = *e++;
const char *p = strchr(s, '=');
if (!p) /* wtf? take next variable */
continue;
/* export var= */
printf("export %.*s", (int)(p - s) + 1, s);
s = p + 1;
while (*s) {
if (*s != '\'') {
p = strchrnul(s, '\'');
/* print 'xxxx' */
printf("'%.*s'", (int)(p - s), s);
if (*p == '\0')
break;
s = p;
}
/* s points to '; print ''...'''" */
putchar('"');
do putchar('\''); while (*++s == '\'');
putchar('"');
}
putchar('\n');
#endif
}
fflush(stdout);
}
return EXIT_SUCCESS;
}
do {
const char *value;
char *name = *argv;
value = strchr(name, '=');
if (!value) {
/* They are exporting something without a =VALUE */
struct variable *var;
var = get_local_var(name);
if (var) {
var->flg_export = 1;
debug_printf_env("%s: putenv '%s'\n", __func__, var->varstr);
putenv(var->varstr);
}
/* bash does not return an error when trying to export
* an undefined variable. Do likewise. */
continue;
}
set_local_var(xstrdup(name), 1, 0);
} while (*++argv);
return EXIT_SUCCESS;
}
#if ENABLE_HUSH_JOB
/* built-in 'fg' and 'bg' handler */
static int builtin_fg_bg(char **argv)
{
int i, jobnum;
struct pipe *pi;
if (!G_interactive_fd)
return EXIT_FAILURE;
/* If they gave us no args, assume they want the last backgrounded task */
if (!argv[1]) {
for (pi = G.job_list; pi; pi = pi->next) {
if (pi->jobid == G.last_jobid) {
goto found;
}
}
bb_error_msg("%s: no current job", argv[0]);
return EXIT_FAILURE;
}
if (sscanf(argv[1], "%%%d", &jobnum) != 1) {
bb_error_msg("%s: bad argument '%s'", argv[0], argv[1]);
return EXIT_FAILURE;
}
for (pi = G.job_list; pi; pi = pi->next) {
if (pi->jobid == jobnum) {
goto found;
}
}
bb_error_msg("%s: %d: no such job", argv[0], jobnum);
return EXIT_FAILURE;
found:
// TODO: bash prints a string representation
// of job being foregrounded (like "sleep 1 | cat")
if (argv[0][0] == 'f') {
/* Put the job into the foreground. */
tcsetpgrp(G_interactive_fd, pi->pgrp);
}
/* Restart the processes in the job */
debug_printf_jobs("reviving %d procs, pgrp %d\n", pi->num_cmds, pi->pgrp);
for (i = 0; i < pi->num_cmds; i++) {
debug_printf_jobs("reviving pid %d\n", pi->cmds[i].pid);
pi->cmds[i].is_stopped = 0;
}
pi->stopped_cmds = 0;
i = kill(- pi->pgrp, SIGCONT);
if (i < 0) {
if (errno == ESRCH) {
delete_finished_bg_job(pi);
return EXIT_SUCCESS;
}
bb_perror_msg("kill (SIGCONT)");
}
if (argv[0][0] == 'f') {
remove_bg_job(pi);
return checkjobs_and_fg_shell(pi);
}
return EXIT_SUCCESS;
}
#endif
#if ENABLE_HUSH_HELP
static int builtin_help(char **argv UNUSED_PARAM)
{
const struct built_in_command *x;
printf("\n"
"Built-in commands:\n"
"------------------\n");
for (x = bltins; x != &bltins[ARRAY_SIZE(bltins)]; x++) {
printf("%s\t%s\n", x->cmd, x->descr);
}
printf("\n\n");
return EXIT_SUCCESS;
}
#endif
#if ENABLE_HUSH_JOB
static int builtin_jobs(char **argv UNUSED_PARAM)
{
struct pipe *job;
const char *status_string;
for (job = G.job_list; job; job = job->next) {
if (job->alive_cmds == job->stopped_cmds)
status_string = "Stopped";
else
status_string = "Running";
printf(JOB_STATUS_FORMAT, job->jobid, status_string, job->cmdtext);
}
return EXIT_SUCCESS;
}
#endif
#if HUSH_DEBUG
static int builtin_memleak(char **argv UNUSED_PARAM)
{
void *p;
unsigned long l;
/* Crude attempt to find where "free memory" starts,
* sans fragmentation. */
p = malloc(240);
l = (unsigned long)p;
free(p);
p = malloc(3400);
if (l < (unsigned long)p) l = (unsigned long)p;
free(p);
if (!G.memleak_value)
G.memleak_value = l;
l -= G.memleak_value;
if ((long)l < 0)
l = 0;
l /= 1024;
if (l > 127)
l = 127;
/* Exitcode is "how many kilobytes we leaked since 1st call" */
return l;
}
#endif
static int builtin_pwd(char **argv UNUSED_PARAM)
{
puts(set_cwd());
return EXIT_SUCCESS;
}
static int builtin_read(char **argv)
{
char *string;
const char *name = "REPLY";
if (argv[1]) {
name = argv[1];
/* bash (3.2.33(1)) bug: "read 0abcd" will execute,
* and _after_ that_ it will complain */
if (!is_well_formed_var_name(name, '\0')) {
/* Mimic bash message */
bb_error_msg("read: '%s': not a valid identifier", name);
return 1;
}
}
//TODO: bash unbackslashes input, splits words and puts them in argv[i]
string = xmalloc_reads(STDIN_FILENO, xasprintf("%s=", name), NULL);
return set_local_var(string, 0, 0);
}
/* http://www.opengroup.org/onlinepubs/9699919799/utilities/V3_chap02.html#set
* built-in 'set' handler
* SUSv3 says:
* set [-abCefhmnuvx] [-o option] [argument...]
* set [+abCefhmnuvx] [+o option] [argument...]
* set -- [argument...]
* set -o
* set +o
* Implementations shall support the options in both their hyphen and
* plus-sign forms. These options can also be specified as options to sh.
* Examples:
* Write out all variables and their values: set
* Set $1, $2, and $3 and set "$#" to 3: set c a b
* Turn on the -x and -v options: set -xv
* Unset all positional parameters: set --
* Set $1 to the value of x, even if it begins with '-' or '+': set -- "$x"
* Set the positional parameters to the expansion of x, even if x expands
* with a leading '-' or '+': set -- $x
*
* So far, we only support "set -- [argument...]" and some of the short names.
*/
static int builtin_set(char **argv)
{
int n;
char **pp, **g_argv;
char *arg = *++argv;
if (arg == NULL) {
struct variable *e;
for (e = G.top_var; e; e = e->next)
puts(e->varstr);
return EXIT_SUCCESS;
}
do {
if (!strcmp(arg, "--")) {
++argv;
goto set_argv;
}
if (arg[0] != '+' && arg[0] != '-')
break;
for (n = 1; arg[n]; ++n)
if (set_mode(arg[0], arg[n]))
goto error;
} while ((arg = *++argv) != NULL);
/* Now argv[0] is 1st argument */
if (arg == NULL)
return EXIT_SUCCESS;
set_argv:
/* NB: G.global_argv[0] ($0) is never freed/changed */
g_argv = G.global_argv;
if (G.global_args_malloced) {
pp = g_argv;
while (*++pp)
free(*pp);
g_argv[1] = NULL;
} else {
G.global_args_malloced = 1;
pp = xzalloc(sizeof(pp[0]) * 2);
pp[0] = g_argv[0]; /* retain $0 */
g_argv = pp;
}
/* This realloc's G.global_argv */
G.global_argv = pp = add_strings_to_strings(g_argv, argv, /*dup:*/ 1);
n = 1;
while (*++pp)
n++;
G.global_argc = n;
return EXIT_SUCCESS;
/* Nothing known, so abort */
error:
bb_error_msg("set: %s: invalid option", arg);
return EXIT_FAILURE;
}
static int builtin_shift(char **argv)
{
int n = 1;
if (argv[1]) {
n = atoi(argv[1]);
}
if (n >= 0 && n < G.global_argc) {
if (G.global_args_malloced) {
int m = 1;
while (m <= n)
free(G.global_argv[m++]);
}
G.global_argc -= n;
memmove(&G.global_argv[1], &G.global_argv[n+1],
G.global_argc * sizeof(G.global_argv[0]));
return EXIT_SUCCESS;
}
return EXIT_FAILURE;
}
static int builtin_source(char **argv)
{
FILE *input;
if (*++argv == NULL)
return EXIT_FAILURE;
/* XXX search through $PATH is missing */
input = fopen_or_warn(*argv, "r");
if (!input) {
/* bb_perror_msg("%s", *argv); - done by fopen_or_warn */
return EXIT_FAILURE;
}
close_on_exec_on(fileno(input));
/* Now run the file */
//TODO:
/* XXX argv and argc are broken; need to save old G.global_argv
* (pointer only is OK!) on this stack frame,
* set G.global_argv=argv+1, recurse, and restore. */
parse_and_run_file(input);
fclose(input);
return G.last_exitcode;
}
static int builtin_umask(char **argv)
{
mode_t new_umask;
const char *arg = argv[1];
if (arg) {
//TODO: umask may take chmod-like symbolic masks
new_umask = bb_strtou(arg, NULL, 8);
if (errno) {
//Message? bash examples:
//bash: umask: 'q': invalid symbolic mode operator
//bash: umask: 999: octal number out of range
return EXIT_FAILURE;
}
} else {
new_umask = umask(0);
printf("%.3o\n", (unsigned) new_umask);
/* fall through and restore new_umask which we set to 0 */
}
umask(new_umask);
return EXIT_SUCCESS;
}
/* http://www.opengroup.org/onlinepubs/9699919799/utilities/V3_chap02.html#unset */
static int builtin_unset(char **argv)
{
int ret;
char var;
if (!*++argv)
return EXIT_SUCCESS;
var = 'v';
if (argv[0][0] == '-') {
switch (argv[0][1]) {
case 'v':
case 'f':
var = argv[0][1];
break;
default:
bb_error_msg("unset: %s: invalid option", *argv);
return EXIT_FAILURE;
}
//TODO: disallow "unset -vf ..." too
argv++;
}
ret = EXIT_SUCCESS;
while (*argv) {
if (var == 'v') {
if (unset_local_var(*argv)) {
/* unset <nonexistent_var> doesn't fail.
* Error is when one tries to unset RO var.
* Message was printed by unset_local_var. */
ret = EXIT_FAILURE;
}
}
//#if ENABLE_HUSH_FUNCTIONS
// else {
// unset_local_func(*argv);
// }
//#endif
argv++;
}
return ret;
}
/* http://www.opengroup.org/onlinepubs/9699919799/utilities/wait.html */
static int builtin_wait(char **argv)
{
int ret = EXIT_SUCCESS;
int status, sig;
if (*++argv == NULL) {
/* Don't care about wait results */
/* Note 1: must wait until there are no more children */
/* Note 2: must be interruptible */
/* Examples:
* $ sleep 3 & sleep 6 & wait
* [1] 30934 sleep 3
* [2] 30935 sleep 6
* [1] Done sleep 3
* [2] Done sleep 6
* $ sleep 3 & sleep 6 & wait
* [1] 30936 sleep 3
* [2] 30937 sleep 6
* [1] Done sleep 3
* ^C <-- after ~4 sec from keyboard
* $
*/
sigaddset(&G.blocked_set, SIGCHLD);
sigprocmask(SIG_SETMASK, &G.blocked_set, NULL);
while (1) {
checkjobs(NULL);
if (errno == ECHILD)
break;
/* Wait for SIGCHLD or any other signal of interest */
/* sigtimedwait with infinite timeout: */
sig = sigwaitinfo(&G.blocked_set, NULL);
if (sig > 0) {
sig = check_and_run_traps(sig);
if (sig && sig != SIGCHLD) { /* see note 2 */
ret = 128 + sig;
break;
}
}
}
sigdelset(&G.blocked_set, SIGCHLD);
sigprocmask(SIG_SETMASK, &G.blocked_set, NULL);
return ret;
}
/* This is probably buggy wrt interruptible-ness */
while (*argv) {
pid_t pid = bb_strtou(*argv, NULL, 10);
if (errno) {
/* mimic bash message */
bb_error_msg("wait: '%s': not a pid or valid job spec", *argv);
return EXIT_FAILURE;
}
if (waitpid(pid, &status, 0) == pid) {
if (WIFSIGNALED(status))
ret = 128 + WTERMSIG(status);
else if (WIFEXITED(status))
ret = WEXITSTATUS(status);
else /* wtf? */
ret = EXIT_FAILURE;
} else {
bb_perror_msg("wait %s", *argv);
ret = 127;
}
argv++;
}
return ret;
}
#if ENABLE_HUSH_LOOPS
static int builtin_break(char **argv)
{
if (G.depth_of_loop == 0) {
bb_error_msg("%s: only meaningful in a loop", argv[0]);
return EXIT_SUCCESS; /* bash compat */
}
G.flag_break_continue++; /* BC_BREAK = 1 */
G.depth_break_continue = 1;
if (argv[1]) {
G.depth_break_continue = bb_strtou(argv[1], NULL, 10);
if (errno || !G.depth_break_continue || argv[2]) {
bb_error_msg("%s: bad arguments", argv[0]);
G.flag_break_continue = BC_BREAK;
G.depth_break_continue = UINT_MAX;
}
}
if (G.depth_of_loop < G.depth_break_continue)
G.depth_break_continue = G.depth_of_loop;
return EXIT_SUCCESS;
}
static int builtin_continue(char **argv)
{
G.flag_break_continue = 1; /* BC_CONTINUE = 2 = 1+1 */
return builtin_break(argv);
}
#endif