/** \file builtin_commandline.c Functions defining the commandline builtin Functions used for implementing the commandline builtin. */ #include #include #include #include #include #include #include #include #include "config.h" #include "util.h" #include "builtin.h" #include "common.h" #include "wgetopt.h" struct resource_t { int resource; const wchar_t *desc; wchar_t switch_char; } ; const static struct resource_t resource_arr[] = { { RLIMIT_CORE, L"Maximum size of core files created", L'c' } , { RLIMIT_DATA, L"Maximum size of a process’s data segment", L'd' } , { RLIMIT_FSIZE, L"Maximum size of files created by the shell", L'f' } , { RLIMIT_MEMLOCK, L"Maximum size that may be locked into memory", L'l' } , { RLIMIT_RSS, L"Maximum resident set size", L'm' } , { RLIMIT_NOFILE, L"Maximum number of open file descriptors", L'n' } , { RLIMIT_STACK, L"Maximum stack size", L's' } , { RLIMIT_CPU, L"Maximum amount of cpu time in seconds", L't' } , { RLIMIT_NPROC, L"Maximum number of processes available to a single user", L'u' } , #if HAVE_RLIMIT_AS { RLIMIT_AS, L"Maximum amount of virtual memory available to the shell", L'v' } , #endif { 0, 0 } } ; static int get_multiplier( int what ) { if( ( what == RLIMIT_NPROC ) || ( what == RLIMIT_NOFILE ) || ( what == RLIMIT_CPU ) ) { return 1; } return 1024; } static rlim_t get( int resource, int hard ) { struct rlimit ls; getrlimit( resource, &ls ); return hard ? ls.rlim_max:ls.rlim_cur; } static void print( int resource, int hard ) { rlim_t l = get( resource, hard ); if( l == RLIM_INFINITY ) sb_append( sb_out, L"unlimited\n" ); else sb_printf( sb_out, L"%d\n", l ); } static void print_all( int hard ) { int i; int w=0; for( i=0; resource_arr[i].desc; i++ ) { w=maxi( w, my_wcswidth(resource_arr[i].desc)); } for( i=0; resource_arr[i].desc; i++ ) { struct rlimit ls; rlim_t l; getrlimit( resource_arr[i].resource, &ls ); l = hard ? ls.rlim_max:ls.rlim_cur; wchar_t *unit = ((resource_arr[i].resource==RLIMIT_CPU)?L"(seconds, ":(get_multiplier(resource_arr[i].resource)==1?L"(":L"(kB, ")); sb_printf( sb_out, L"%-*ls %10ls-%lc) ", w, resource_arr[i].desc, unit, resource_arr[i].switch_char); if( l == RLIM_INFINITY ) sb_append( sb_out, L"unlimited\n" ); else sb_printf( sb_out, L"%d\n", l ); } } static const wchar_t *get_desc( int what ) { int i; for( i=0; resource_arr[i].desc; i++ ) { if( resource_arr[i].resource == what ) { return resource_arr[i].desc; } } return L"Not a resource"; } static int set( int resource, int hard, int soft, rlim_t value ) { struct rlimit ls; getrlimit( resource, &ls ); if( value != RLIM_INFINITY ) value *= get_multiplier( resource ); if( hard ) { ls.rlim_max = value; } if( soft ) { ls.rlim_cur = value; /* Do not attempt to set the soft limit higher than the hard limit */ if( ( value == RLIM_INFINITY && ls.rlim_max != RLIM_INFINITY ) || ( value != RLIM_INFINITY && ls.rlim_max != RLIM_INFINITY && value > ls.rlim_max)) { ls.rlim_cur = ls.rlim_max; } } if( setrlimit( resource, &ls ) ) { if( errno == EPERM ) sb_printf( sb_err, L"ulimit: Permission denied when changing resource of type '%ls'\n", get_desc( resource ) ); else builtin_wperror( L"ulimit" ); return 1; } return 0; } static int set_all( int hard, int soft, rlim_t value ) { int i; int res=0; for( i=0; resource_arr[i].desc; i++ ) { if( set( resource_arr[i].resource, hard, soft, value ) ) res = 1; } return res; } int builtin_ulimit( wchar_t ** argv ) { int hard=0; int soft=0; int what = RLIMIT_FSIZE; int report_all = 0; int argc = builtin_count_args( argv ); woptind=0; while( 1 ) { const static struct woption long_options[] = { { L"all", no_argument, 0, 'a' } , { L"hard", no_argument, 0, 'H' } , { L"soft", no_argument, 0, 'S' } , { L"core-size", no_argument, 0, 'c' } , { L"data-size", no_argument, 0, 'd' } , { L"file-size", no_argument, 0, 'f' } , { L"lock-size", no_argument, 0, 'l' } , { L"resident-set-size", no_argument, 0, 'm' } , { L"file-descriptor-count", no_argument, 0, 'n' } , { L"pipe-size", no_argument, 0, 'p' } , { L"cpu-time", no_argument, 0, 't' } , { L"process-count", no_argument, 0, 'u' } , { L"virtual-memory-size", no_argument, 0, 'v' } , { 0, 0, 0, 0 } } ; int opt_index = 0; int opt = wgetopt_long( argc, argv, L"aHScdflmnptuv", long_options, &opt_index ); if( opt == -1 ) break; switch( opt ) { case 0: if(long_options[opt_index].flag != 0) break; sb_append2( sb_err, argv[0], BUILTIN_ERR_UNKNOWN, L" ", long_options[opt_index].name, L"\n", (void *)0 ); builtin_print_help( argv[0], sb_err ); return 1; case L'a': report_all=1; break; case L'H': hard=1; break; case L'S': soft=1; break; case L'c': what=RLIMIT_CORE; break; case L'd': what=RLIMIT_DATA; break; case L'f': what=RLIMIT_FSIZE; break; case L'l': what=RLIMIT_MEMLOCK; break; case L'm': what=RLIMIT_RSS; break; case L'n': what=RLIMIT_NOFILE; break; case L's': what=RLIMIT_STACK; break; case L't': what=RLIMIT_CPU; break; case L'u': what=RLIMIT_NPROC; break; #if HAVE_RLIMIT_AS case L'v': what=RLIMIT_AS; break; #endif case L'?': builtin_print_help( argv[0], sb_err ); return 1; } } switch( argc - woptind ) { case 0: /* Show current limit value */ if( report_all ) { print_all( hard ); } else { print( what, hard ); } break; case 1: { /* Change current limit value */ rlim_t new_limit; wchar_t *end; /* Set both hard and soft limits if nothing else was specified */ if( !(hard+soft) ) { hard=soft=1; } if( wcscasecmp( argv[woptind], L"unlimited" )==0) { new_limit = RLIM_INFINITY; } else if( wcscasecmp( argv[woptind], L"hard" )==0) { new_limit = get( what, 1 ); } else if( wcscasecmp( argv[woptind], L"soft" )==0) { new_limit = get( what, soft ); } else { errno=0; new_limit = wcstol( argv[woptind], &end, 10 ); if( errno || *end ) { sb_printf( sb_err, L"%ls: Invalid limit '%ls'\n", argv[0], argv[woptind] ); builtin_print_help( argv[0], sb_err ); return 1; } } if( report_all ) { return set_all( hard, soft, new_limit ); } else { return set( what, hard, soft, new_limit ); } break; } default: sb_append2( sb_err, argv[0], L": Too many arguments\n", (void *)0 ); builtin_print_help( argv[0], sb_err ); return 1; break; } return 0; }