/* Process information queries Copyright (C) 1992, 1993, 1994, 1995 Free Software Foundation This file is part of the GNU Hurd. The GNU Hurd is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. The GNU Hurd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with the GNU Hurd; see the file COPYING. If not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ /* Written by Michael I. Bushnell. */ #include #include #include #include #include #include #include #include #include "proc.h" #include "process_S.h" /* Implement S_proc_pid2task as described in . */ kern_return_t S_proc_pid2task (struct proc *callerp, pid_t pid, task_t *t) { struct proc *p = pid_find (pid); if (!p) return ESRCH; if (!check_uid (callerp, p->p_owner)) return EPERM; *t = p->p_task; return 0; } /* Implement proc_task2pid as described in . */ kern_return_t S_proc_task2pid (struct proc *callerp, task_t t, pid_t *pid) { struct proc *p = task_find (t); if (!p) return ESRCH; *pid = p->p_pid; mach_port_deallocate (mach_task_self (), t); return 0; } /* Implement proc_task2proc as described in . */ kern_return_t S_proc_task2proc (struct proc *callerp, task_t t, mach_port_t *outproc) { struct proc *p = task_find (t); if (!p) return ESRCH; *outproc = p->p_reqport; mach_port_deallocate (mach_task_self (), t); return 0; } /* Implement proc_proc2task as described in . */ kern_return_t S_proc_proc2task (struct proc *p, task_t *t) { *t = p->p_task; return 0; } /* Implement proc_pid2proc as described in . */ kern_return_t S_proc_pid2proc (struct proc *callerp, pid_t pid, mach_port_t *outproc) { struct proc *p = pid_find (pid); if (!p) return ESRCH; if (!check_uid (callerp, p->p_owner)) return EPERM; *outproc = p->p_reqport; return 0; } /* Read a string starting at address ADDR in task T; set *STR to point at newly malloced storage holding it. */ static error_t get_string (task_t t, vm_address_t addr, char **str) { /* This version assumes that a string is never more than one page in length. */ vm_address_t readaddr; vm_address_t data; u_int readlen; error_t err; char *c; readaddr = trunc_page (addr); err = vm_read (t, readaddr, vm_page_size * 2, &data, &readlen); if (err == KERN_INVALID_ADDRESS) err = vm_read (t, readaddr, vm_page_size, &data, &readlen); if (err == MACH_SEND_INVALID_DEST) err = ESRCH; if (err) return err; /* Scan for a null. */ c = memchr ((char *) (data + (addr - readaddr)), '\0', readlen - (addr - readaddr)); if (c == NULL) err = KERN_INVALID_ADDRESS; else { c++; /* Include the null. */ *str = malloc (c - (char *)(data + (addr - readaddr))); if (*str == NULL) err = ENOMEM; else bcopy ((char *)(data + (addr - readaddr)), *str, c - (char *)(data + (addr - readaddr))); } vm_deallocate (mach_task_self (), data, readlen); return err; } /* Read a vector of addresses (stored as are argv and envp) from tast TASK found at address ADDR. Set *VEC to point to newly malloced storage holding the addresses. */ static error_t get_vector (task_t task, vm_address_t addr, int **vec) { vm_address_t readaddr; vm_address_t data = 0; u_int readlen; error_t err; vm_address_t *t; readaddr = trunc_page (addr); err = vm_read (task, readaddr, vm_page_size * 2, &data, &readlen); if (err == KERN_INVALID_ADDRESS) err = vm_read (task, readaddr, vm_page_size, &data, &readlen); if (err == MACH_SEND_INVALID_DEST) err = ESRCH; if (err) return err; /* Scan for a null. */ *vec = 0; /* This will lose sometimes on machines with unfortunate alignment restrictions. XXX */ for (t = (vm_address_t *) (data + (addr - readaddr)); t < (vm_address_t *) (data + readlen); ++t) if (*t == 0) { ++t; /* Include the null. */ *vec = malloc ((char *)t - (char *)(data + (addr - readaddr))); if (*vec == NULL) { err = ENOMEM; break; } bcopy ((char *)(data + (addr - readaddr)), *vec, (char *)t - (char *)(data + (addr - readaddr))); break; } if (!err && *vec == 0) err = KERN_INVALID_ADDRESS; vm_deallocate (mach_task_self (), data, readlen); return err; } /* Fetch an array of strings at address LOC in task T into BUF of size BUFLEN. */ static error_t get_string_array (task_t t, vm_address_t loc, vm_address_t *buf, u_int *buflen) { char *bp; int *vector, *vp; error_t err; vm_address_t origbuf = *buf; err = get_vector (t, loc, &vector); if (err) return err; bp = (char *) *buf; for (vp = vector; *vp; ++vp) { char *string; int len; err = get_string (t, *vp, &string); if (err) { free (vector); if (*buf != origbuf) vm_deallocate (mach_task_self (), *buf, *buflen); return err; } len = strlen (string) + 1; if (len > (char *) *buf + *buflen - bp) { vm_address_t newbuf; err = vm_allocate (mach_task_self (), &newbuf, *buflen * 2, 1); if (err) { free (string); free (vector); if (*buf != origbuf) vm_deallocate (mach_task_self (), *buf, *buflen); return err; } bcopy (*(char **)buf, (void *)newbuf, (vm_address_t) bp - newbuf); bp = newbuf + (bp - *buf); if (*buf != origbuf) vm_deallocate (mach_task_self (), *buf, *buflen); *buf = newbuf; *buflen *= 2; } bcopy (string, bp, len); bp += len; free (string); } free (vector); *buflen = bp - (char *) *buf; return 0; } /* Implement proc_getprocargs as described in . */ kern_return_t S_proc_getprocargs (struct proc *callerp, pid_t pid, char **buf, u_int *buflen) { struct proc *p = pid_find (pid); if (!p) return ESRCH; return get_string_array (p->p_task, p->p_argv, (vm_address_t *) buf, buflen); } /* Implement proc_getprocenv as described in . */ kern_return_t S_proc_getprocenv (struct proc *callerp, pid_t pid, char **buf, u_int *buflen) { struct proc *p = pid_find (pid); if (!p) return ESRCH; return get_string_array (p->p_task, p->p_envp, (vm_address_t *)buf, buflen); } /* Implement proc_getprocinfo as described in . */ kern_return_t S_proc_getprocinfo (struct proc *callerp, pid_t pid, int flags, int **piarray, u_int *piarraylen, char **noise, unsigned *noise_len) { struct proc *p = pid_find (pid); struct procinfo *pi; int nthreads; thread_t *thds; error_t err = 0; size_t structsize; int i; int didalloc = 0; u_int tkcount, thcount; struct proc *tp; if (!p) return ESRCH; if (flags & (PI_FETCH_THREAD_SCHED | PI_FETCH_THREAD_BASIC | PI_FETCH_THREAD_WAITS)) flags |= PI_FETCH_THREADS; if (flags & PI_FETCH_THREADS) { err = task_threads (p->p_task, &thds, &nthreads); if (err == MACH_SEND_INVALID_DEST) err = ESRCH; if (err) return err; } else nthreads = 0; structsize = sizeof (struct procinfo) + nthreads * sizeof (pi->threadinfos[0]); if (structsize / sizeof (int) > *piarraylen) { vm_allocate (mach_task_self (), (u_int *)piarray, structsize, 1); didalloc = 1; } *piarraylen = structsize / sizeof (int); pi = (struct procinfo *) *piarray; pi->state = ((p->p_stopped ? PI_STOPPED : 0) | (p->p_exec ? PI_EXECED : 0) | (p->p_waiting ? PI_WAITING : 0) | (!p->p_pgrp->pg_orphcnt ? PI_ORPHAN : 0) | (p->p_msgport == MACH_PORT_NULL ? PI_NOMSG : 0) | (p->p_pgrp->pg_session->s_sid == p->p_pid ? PI_SESSLD : 0) | (p->p_noowner ? PI_NOTOWNED : 0) | (!p->p_parentset ? PI_NOPARENT : 0) | (p->p_traced ? PI_TRACED : 0) | (p->p_msgportwait ? PI_GETMSG : 0) | (p->p_loginleader ? PI_LOGINLD : 0)); pi->owner = p->p_owner; pi->ppid = p->p_parent->p_pid; pi->pgrp = p->p_pgrp->pg_pgid; pi->session = p->p_pgrp->pg_session->s_sid; for (tp = p; !tp->p_loginleader; tp = tp->p_parent) assert (tp); pi->logincollection = tp->p_pid; pi->nthreads = nthreads; if (flags & PI_FETCH_TASKINFO) { tkcount = TASK_BASIC_INFO_COUNT; err = task_info (p->p_task, TASK_BASIC_INFO, (int *)&pi->taskinfo, &tkcount); if (err == MACH_SEND_INVALID_DEST) err = ESRCH; } for (i = 0; i < nthreads; i++) { pi->threadinfos[i].died = 0; if (flags & PI_FETCH_THREAD_BASIC) { thcount = THREAD_BASIC_INFO_COUNT; err = thread_info (thds[i], THREAD_BASIC_INFO, (int *)&pi->threadinfos[i].pis_bi, &thcount); if (err == MACH_SEND_INVALID_DEST) { pi->threadinfos[i].died = 1; continue; } if (err && err != MACH_SEND_INVALID_DEST) break; } if (flags & PI_FETCH_THREAD_SCHED) { thcount = THREAD_SCHED_INFO_COUNT; if (!err) err = thread_info (thds[i], THREAD_SCHED_INFO, (int *)&pi->threadinfos[i].pis_si, &thcount); if (err == MACH_SEND_INVALID_DEST) { pi->threadinfos[i].died = 1; continue; } if (err && err != ESRCH) break; } if (flags & PI_FETCH_THREAD_WAITS) /* Errors are not significant here. */ msg_report_wait (p->p_msgport, thds[i], &pi->threadinfos[i].rpc_block); mach_port_deallocate (mach_task_self (), thds[i]); } if (flags & PI_FETCH_THREADS) { vm_deallocate (mach_task_self (), (u_int )thds, nthreads * sizeof (thread_t)); } if (err && didalloc) vm_deallocate (mach_task_self (), (u_int) *piarray, structsize); if (!err) /* Don't return anything for now. */ *noise_len = 0; return err; } /* Implement proc_make_login_coll as described in . */ kern_return_t S_proc_make_login_coll (struct proc *p) { p->p_loginleader = 1; return 0; } /* Implement proc_getloginid as described in . */ kern_return_t S_proc_getloginid (struct proc *callerp, pid_t pid, pid_t *leader) { struct proc *proc = pid_find (pid); struct proc *p; if (!proc) return ESRCH; for (p = proc; !p->p_loginleader; p = p->p_parent) assert (p); *leader = p->p_pid; return 0; } /* Implement proc_getloginpids as described in . */ kern_return_t S_proc_getloginpids (struct proc *callerp, pid_t id, pid_t **pids, u_int *npids) { struct proc *l = pid_find (id); struct proc *p; struct proc **tail, **new, **parray; int parraysize; int i; if (!l || !l->p_loginleader) return ESRCH; /* Simple breadth first search of the children of L. */ parraysize = 50; parray = malloc (sizeof (struct proc *) * parraysize); parray[0] = l; for (tail = parray, new = &parray[1]; tail != new; tail++) { for (p = (*tail)->p_ochild; p; p = p->p_sib) if (!p->p_loginleader) { /* Add P to the list at NEW */ if (new - parray > parraysize) { struct proc **newparray; newparray = realloc (parray, ((parraysize *= 2) * sizeof (struct proc *))); tail = newparray + (tail - parray); new = newparray + (new - parray); parray = newparray; } *new++ = p; } } if (*npids < new - parray) vm_allocate (mach_task_self (), (vm_address_t *) pids, (new - parray) * sizeof (pid_t), 1); *npids = new - parray; for (i = 0; i < *npids; i++) (*pids)[i] = parray[i]->p_pid; free (parray); return 0; } /* Implement proc_setlogin as described in . */ kern_return_t S_proc_setlogin (struct proc *p, char *login) { struct login *l; if (!check_uid (p, 0)) return EPERM; l = malloc (sizeof (struct login) + strlen (login) + 1); l->l_refcnt = 1; strcpy (l->l_name, login); if (!--p->p_login->l_refcnt) free (p->p_login); p->p_login = l; return 0; } /* Implement proc_getlogin as described in . */ kern_return_t S_proc_getlogin (struct proc *p, char *login) { strcpy (login, p->p_login->l_name); return 0; }