/* This file contains some utility routines for RS. * * Changes: * Nov 22, 2009: Created (Cristiano Giuffrida) */ #include "inc.h" #include #include #include "kernel/proc.h" /*===========================================================================* * init_service * *===========================================================================*/ int init_service(rp, type) struct rproc *rp; /* pointer to process slot */ int type; /* type of initialization */ { int r; message m; struct rprocpub *rpub; endpoint_t old_endpoint; rpub = rp->r_pub; rp->r_flags |= RS_INITIALIZING; /* now initializing */ rp->r_check_tm = rp->r_alive_tm + 1; /* expect reply within period */ /* In case of RS initialization, we are done. */ if(rp->r_priv.s_flags & ROOT_SYS_PROC) { return OK; } /* Determine the old endpoint if this is a new instance. */ old_endpoint = NONE; if(rp->r_old_rp) { old_endpoint = rp->r_old_rp->r_pub->endpoint; } else if(rp->r_prev_rp) { old_endpoint = rp->r_prev_rp->r_pub->endpoint; } /* Send initialization message. */ m.m_type = RS_INIT; m.RS_INIT_TYPE = type; m.RS_INIT_RPROCTAB_GID = rinit.rproctab_gid; m.RS_INIT_OLD_ENDPOINT = old_endpoint; r = asynsend(rpub->endpoint, &m); return r; } /*===========================================================================* * fill_send_mask * *===========================================================================*/ void fill_send_mask(send_mask, set_bits) sys_map_t *send_mask; /* the send mask to fill in */ int set_bits; /* TRUE sets all bits, FALSE clears all bits */ { /* Fill in a send mask. */ int i; for (i = 0; i < NR_SYS_PROCS; i++) { if (set_bits) set_sys_bit(*send_mask, i); else unset_sys_bit(*send_mask, i); } } /*===========================================================================* * fill_call_mask * *===========================================================================*/ void fill_call_mask(calls, tot_nr_calls, call_mask, call_base, is_init) int *calls; /* the unordered set of calls */ int tot_nr_calls; /* the total number of calls */ bitchunk_t *call_mask; /* the call mask to fill in */ int call_base; /* the base offset for the calls */ int is_init; /* set when initializing a call mask */ { /* Fill a call mask from an unordered set of calls. */ int i; int call_mask_size, nr_calls; call_mask_size = BITMAP_CHUNKS(tot_nr_calls); /* Count the number of calls to fill in. */ nr_calls = 0; for(i=0; calls[i] != NULL_C; i++) { nr_calls++; } /* See if all calls are allowed and call mask must be completely filled. */ if(nr_calls == 1 && calls[0] == ALL_C) { for(i=0; i < call_mask_size; i++) { call_mask[i] = (~0); } } else { /* When initializing, reset the mask first. */ if(is_init) { for(i=0; i < call_mask_size; i++) { call_mask[i] = 0; } } /* Enter calls bit by bit. */ for(i=0; i < nr_calls; i++) { SET_BIT(call_mask, calls[i] - call_base); } } } /*===========================================================================* * srv_to_string * *===========================================================================*/ char* srv_to_string(rp) struct rproc *rp; /* pointer to process slot */ { struct rprocpub *rpub; int slot_nr; char *srv_string; static char srv_string_pool[3][RS_MAX_LABEL_LEN + (DEBUG ? 256 : 64)]; static int srv_string_pool_index = 0; rpub = rp->r_pub; slot_nr = rp - rproc; srv_string = srv_string_pool[srv_string_pool_index]; srv_string_pool_index = (srv_string_pool_index + 1) % 3; #define srv_str(cmd) ((cmd) == NULL || (cmd)[0] == '\0' ? "_" : (cmd)) #define srv_ep_str(rp) (itoa((rp)->r_pub->endpoint)) #define srv_active_str(rp) ((rp)->r_flags & RS_ACTIVE ? "*" : " ") #define srv_version_str(rp) ((rp)->r_new_rp || (rp)->r_next_rp ? "-" : \ ((rp)->r_old_rp || (rp)->r_prev_rp ? "+" : " ")) #if DEBUG sprintf(srv_string, "service '%s'%s%s(slot %d, ep %d, pid %d, cmd %s, script %s, proc %s, major %d, style %d, flags 0x%03x, sys_flags 0x%02x)", rpub->label, srv_active_str(rp), srv_version_str(rp), slot_nr, rpub->endpoint, rp->r_pid, srv_str(rp->r_cmd), srv_str(rp->r_script), srv_str(rpub->proc_name), rpub->dev_nr, rpub->dev_style, rp->r_flags, rpub->sys_flags); #else sprintf(srv_string, "service '%s'%s%s(slot %d, ep %d, pid %d)", rpub->label, srv_active_str(rp), srv_version_str(rp), slot_nr, rpub->endpoint, rp->r_pid); #endif return srv_string; } /*===========================================================================* * reply * *===========================================================================*/ void reply(who, rp, m_ptr) endpoint_t who; /* replyee */ struct rproc *rp; /* replyee slot (if any) */ message *m_ptr; /* reply message */ { int r; /* send status */ /* No need to actually reply to RS */ if(who == RS_PROC_NR) { return; } if(rs_verbose && rp) printf("RS: %s being replied to\n", srv_to_string(rp)); r = sendnb(who, m_ptr); /* send the message */ if (r != OK) printf("RS: unable to send reply to %d: %d\n", who, r); } /*===========================================================================* * late_reply * *===========================================================================*/ void late_reply(rp, code) struct rproc *rp; /* pointer to process slot */ int code; /* status code */ { /* If a caller is waiting for a reply, unblock it. */ if(rp->r_flags & RS_LATEREPLY) { message m; m.m_type = code; if(rs_verbose) printf("RS: %s late reply %d to %d for request %d\n", srv_to_string(rp), code, rp->r_caller, rp->r_caller_request); reply(rp->r_caller, NULL, &m); rp->r_flags &= ~RS_LATEREPLY; } } /*===========================================================================* * rs_isokendpt * *===========================================================================*/ int rs_isokendpt(endpoint_t endpoint, int *proc) { *proc = _ENDPOINT_P(endpoint); if(*proc < -NR_TASKS || *proc >= NR_PROCS) return EINVAL; return OK; } /*===========================================================================* * sched_init_proc * *===========================================================================*/ int sched_init_proc(struct rproc *rp) { int s; int is_usr_proc; /* Make sure user processes have no scheduler. PM deals with them. */ is_usr_proc = !(rp->r_priv.s_flags & SYS_PROC); if(is_usr_proc) assert(rp->r_scheduler == NONE); if(!is_usr_proc) assert(rp->r_scheduler != NONE); /* Start scheduling for the given process. */ if ((s = sched_start(rp->r_scheduler, rp->r_pub->endpoint, RS_PROC_NR, rp->r_priority, rp->r_quantum, rp->r_cpu, &rp->r_scheduler)) != OK) { return s; } return s; } /*===========================================================================* * update_sig_mgrs * *===========================================================================*/ int update_sig_mgrs(struct rproc *rp, endpoint_t sig_mgr, endpoint_t bak_sig_mgr) { int r; struct rprocpub *rpub; rpub = rp->r_pub; if(rs_verbose) printf("RS: %s updates signal managers: %d%s / %d\n", srv_to_string(rp), sig_mgr == SELF ? rpub->endpoint : sig_mgr, sig_mgr == SELF ? "(SELF)" : "", bak_sig_mgr == NONE ? -1 : bak_sig_mgr); /* Synch privilege structure with the kernel. */ if ((r = sys_getpriv(&rp->r_priv, rpub->endpoint)) != OK) { printf("unable to synch privilege structure: %d", r); return r; } /* Set signal managers. */ rp->r_priv.s_sig_mgr = sig_mgr; rp->r_priv.s_bak_sig_mgr = bak_sig_mgr; /* Update privilege structure. */ r = sys_privctl(rpub->endpoint, SYS_PRIV_UPDATE_SYS, &rp->r_priv); if(r != OK) { printf("unable to update privilege structure: %d", r); return r; } return OK; }