/* This task provides an interface between the kernel and user-space system * processes. System services can be accessed by doing a kernel call. Kernel * calls are transformed into request messages, which are handled by this * task. By convention, a sys_call() is transformed in a SYS_CALL request * message that is handled in a function named do_call(). * * A private call vector is used to map all kernel calls to the functions that * handle them. The actual handler functions are contained in separate files * to keep this file clean. The call vector is used in the system task's main * loop to handle all incoming requests. * * In addition to the main sys_task() entry point, which starts the main loop, * there are several other minor entry points: * get_priv: assign privilege structure to user or system process * send_sig: send a signal directly to a system process * cause_sig: take action to cause a signal to occur via PM * umap_local: map virtual address in LOCAL_SEG to physical * umap_remote: map virtual address in REMOTE_SEG to physical * umap_bios: map virtual address in BIOS_SEG to physical * virtual_copy: copy bytes from one virtual address to another * get_randomness: accumulate randomness in a buffer * * Changes: * Aug 04, 2005 check if kernel call is allowed (Jorrit N. Herder) * Jul 20, 2005 send signal to services with message (Jorrit N. Herder) * Jan 15, 2005 new, generalized virtual copy function (Jorrit N. Herder) * Oct 10, 2004 dispatch system calls from call vector (Jorrit N. Herder) * Sep 30, 2004 source code documentation updated (Jorrit N. Herder) */ #include "kernel.h" #include "system.h" #include #include #include #include #include #include "protect.h" /* Declaration of the call vector that defines the mapping of kernel calls * to handler functions. The vector is initialized in sys_init() with map(), * which makes sure the kernel call numbers are ok. No space is allocated, * because the dummy is declared extern. If an illegal call is given, the * array size will be negative and this won't compile. */ PUBLIC int (*call_vec[NR_SYS_CALLS])(message *m_ptr); #define map(call_nr, handler) \ {extern int dummy[NR_SYS_CALLS>(unsigned)(call_nr-KERNEL_CALL) ? 1:-1];} \ call_vec[(call_nr-KERNEL_CALL)] = (handler) FORWARD _PROTOTYPE( void initialize, (void)); /*===========================================================================* * sys_task * *===========================================================================*/ PUBLIC void sys_task() { /* Main entry point of sys_task. Get the message and dispatch on type. */ static message m; register int result; register struct proc *caller_ptr; unsigned int call_nr; int s; /* Initialize the system task. */ initialize(); while (TRUE) { /* Get work. Block and wait until a request message arrives. */ receive(ANY, &m); call_nr = (unsigned) m.m_type - KERNEL_CALL; caller_ptr = proc_addr(m.m_source); /* See if the caller made a valid request and try to handle it. */ if (! (priv(caller_ptr)->s_call_mask & (1<= NR_SYS_CALLS) { /* check call number */ kprintf("SYSTEM: illegal request %d from %d.\n", call_nr,m.m_source); result = EBADREQUEST; /* illegal message type */ } else { result = (*call_vec[call_nr])(&m); /* handle the kernel call */ } /* Send a reply, unless inhibited by a handler function. Use the kernel * function lock_send() to prevent a system call trap. The destination * is known to be blocked waiting for a message. */ if (result != EDONTREPLY) { m.m_type = result; /* report status of call */ if (OK != (s=lock_send(m.m_source, &m))) { kprintf("SYSTEM, reply to %d failed: %d\n", m.m_source, s); } } } } /*===========================================================================* * initialize * *===========================================================================*/ PRIVATE void initialize(void) { register struct priv *sp; int i; /* Initialize IRQ handler hooks. Mark all hooks available. */ for (i=0; is_alarm_timer)); } /* Initialize the call vector to a safe default handler. Some kernel calls * may be disabled or nonexistant. Then explicitly map known calls to their * handler functions. This is done with a macro that gives a compile error * if an illegal call number is used. The ordering is not important here. */ for (i=0; is_proc_nr == NONE && sp->s_id != USER_PRIV_ID) break; if (sp->s_proc_nr != NONE) return(ENOSPC); rc->p_priv = sp; /* assign new slot */ rc->p_priv->s_proc_nr = proc_nr(rc); /* set association */ rc->p_priv->s_flags = SYS_PROC; /* mark as privileged */ } else { rc->p_priv = &priv[USER_PRIV_ID]; /* use shared slot */ rc->p_priv->s_proc_nr = INIT_PROC_NR; /* set association */ rc->p_priv->s_flags = 0; /* no initial flags */ } return(OK); } /*===========================================================================* * get_randomness * *===========================================================================*/ PUBLIC void get_randomness(source) int source; { /* On machines with the RDTSC (cycle counter read instruction - pentium * and up), use that for high-resolution raw entropy gathering. Otherwise, * use the realtime clock (tick resolution). * * Unfortunately this test is run-time - we don't want to bother with * compiling different kernels for different machines. * * On machines without RDTSC, we use read_clock(). */ int r_next; unsigned long tsc_high, tsc_low; source %= RANDOM_SOURCES; r_next= krandom.bin[source].r_next; if (machine.processor > 486) { read_tsc(&tsc_high, &tsc_low); krandom.bin[source].r_buf[r_next] = tsc_low; } else { krandom.bin[source].r_buf[r_next] = read_clock(); } if (krandom.bin[source].r_size < RANDOM_ELEMENTS) { krandom.bin[source].r_size ++; } krandom.bin[source].r_next = (r_next + 1 ) % RANDOM_ELEMENTS; } /*===========================================================================* * send_sig * *===========================================================================*/ PUBLIC void send_sig(proc_nr, sig_nr) int proc_nr; /* system process to be signalled */ int sig_nr; /* signal to be sent, 1 to _NSIG */ { /* Notify a system process about a signal. This is straightforward. Simply * set the signal that is to be delivered in the pending signals map and * send a notification with source SYSTEM. */ register struct proc *rp; rp = proc_addr(proc_nr); sigaddset(&priv(rp)->s_sig_pending, sig_nr); lock_notify(SYSTEM, proc_nr); } /*===========================================================================* * cause_sig * *===========================================================================*/ PUBLIC void cause_sig(proc_nr, sig_nr) int proc_nr; /* process to be signalled */ int sig_nr; /* signal to be sent, 1 to _NSIG */ { /* A system process wants to send a signal to a process. Examples are: * - HARDWARE wanting to cause a SIGSEGV after a CPU exception * - TTY wanting to cause SIGINT upon getting a DEL * - FS wanting to cause SIGPIPE for a broken pipe * Signals are handled by sending a message to PM. This function handles the * signals and makes sure the PM gets them by sending a notification. The * process being signaled is blocked while PM has not finished all signals * for it. * Race conditions between calls to this function and the system calls that * process pending kernel signals cannot exist. Signal related functions are * only called when a user process causes a CPU exception and from the kernel * process level, which runs to completion. */ register struct proc *rp; /* Check if the signal is already pending. Process it otherwise. */ rp = proc_addr(proc_nr); if (! sigismember(&rp->p_pending, sig_nr)) { sigaddset(&rp->p_pending, sig_nr); if (! (rp->p_rts_flags & SIGNALED)) { /* other pending */ if (rp->p_rts_flags == 0) lock_dequeue(rp); /* make not ready */ rp->p_rts_flags |= SIGNALED | SIG_PENDING; /* update flags */ send_sig(PM_PROC_NR, SIGKSIG); } } } /*===========================================================================* * umap_local * *===========================================================================*/ PUBLIC phys_bytes umap_local(rp, seg, vir_addr, bytes) register struct proc *rp; /* pointer to proc table entry for process */ int seg; /* T, D, or S segment */ vir_bytes vir_addr; /* virtual address in bytes within the seg */ vir_bytes bytes; /* # of bytes to be copied */ { /* Calculate the physical memory address for a given virtual address. */ vir_clicks vc; /* the virtual address in clicks */ phys_bytes pa; /* intermediate variables as phys_bytes */ phys_bytes seg_base; /* If 'seg' is D it could really be S and vice versa. T really means T. * If the virtual address falls in the gap, it causes a problem. On the * 8088 it is probably a legal stack reference, since "stackfaults" are * not detected by the hardware. On 8088s, the gap is called S and * accepted, but on other machines it is called D and rejected. * The Atari ST behaves like the 8088 in this respect. */ if (bytes <= 0) return( (phys_bytes) 0); if (vir_addr + bytes <= vir_addr) return 0; /* overflow */ vc = (vir_addr + bytes - 1) >> CLICK_SHIFT; /* last click of data */ if (seg != T) seg = (vc < rp->p_memmap[D].mem_vir + rp->p_memmap[D].mem_len ? D : S); if ((vir_addr>>CLICK_SHIFT) >= rp->p_memmap[seg].mem_vir + rp->p_memmap[seg].mem_len) return( (phys_bytes) 0 ); if (vc >= rp->p_memmap[seg].mem_vir + rp->p_memmap[seg].mem_len) return( (phys_bytes) 0 ); seg_base = (phys_bytes) rp->p_memmap[seg].mem_phys; seg_base = seg_base << CLICK_SHIFT; /* segment origin in bytes */ pa = (phys_bytes) vir_addr; pa -= rp->p_memmap[seg].mem_vir << CLICK_SHIFT; return(seg_base + pa); } /*===========================================================================* * umap_remote * *===========================================================================*/ PUBLIC phys_bytes umap_remote(rp, seg, vir_addr, bytes) register struct proc *rp; /* pointer to proc table entry for process */ int seg; /* index of remote segment */ vir_bytes vir_addr; /* virtual address in bytes within the seg */ vir_bytes bytes; /* # of bytes to be copied */ { /* Calculate the physical memory address for a given virtual address. */ struct far_mem *fm; if (bytes <= 0) return( (phys_bytes) 0); if (seg < 0 || seg >= NR_REMOTE_SEGS) return( (phys_bytes) 0); fm = &rp->p_priv->s_farmem[seg]; if (! fm->in_use) return( (phys_bytes) 0); if (vir_addr + bytes > fm->mem_len) return( (phys_bytes) 0); return(fm->mem_phys + (phys_bytes) vir_addr); } /*===========================================================================* * umap_bios * *===========================================================================*/ PUBLIC phys_bytes umap_bios(rp, vir_addr, bytes) register struct proc *rp; /* pointer to proc table entry for process */ vir_bytes vir_addr; /* virtual address in BIOS segment */ vir_bytes bytes; /* # of bytes to be copied */ { /* Calculate the physical memory address at the BIOS. Note: currently, BIOS * address zero (the first BIOS interrupt vector) is not considered as an * error here, but since the physical address will be zero as well, the * calling function will think an error occurred. This is not a problem, * since no one uses the first BIOS interrupt vector. */ /* Check all acceptable ranges. */ if (vir_addr >= BIOS_MEM_BEGIN && vir_addr + bytes <= BIOS_MEM_END) return (phys_bytes) vir_addr; else if (vir_addr >= BASE_MEM_TOP && vir_addr + bytes <= UPPER_MEM_END) return (phys_bytes) vir_addr; kprintf("Warning, error in umap_bios, virtual address 0x%x\n", vir_addr); return 0; } /*===========================================================================* * virtual_copy * *===========================================================================*/ PUBLIC int virtual_copy(src_addr, dst_addr, bytes) struct vir_addr *src_addr; /* source virtual address */ struct vir_addr *dst_addr; /* destination virtual address */ vir_bytes bytes; /* # of bytes to copy */ { /* Copy bytes from virtual address src_addr to virtual address dst_addr. * Virtual addresses can be in ABS, LOCAL_SEG, REMOTE_SEG, or BIOS_SEG. */ struct vir_addr *vir_addr[2]; /* virtual source and destination address */ phys_bytes phys_addr[2]; /* absolute source and destination */ int seg_index; int i; /* Check copy count. */ if (bytes <= 0) return(EDOM); /* Do some more checks and map virtual addresses to physical addresses. */ vir_addr[_SRC_] = src_addr; vir_addr[_DST_] = dst_addr; for (i=_SRC_; i<=_DST_; i++) { /* Get physical address. */ switch((vir_addr[i]->segment & SEGMENT_TYPE)) { case LOCAL_SEG: seg_index = vir_addr[i]->segment & SEGMENT_INDEX; phys_addr[i] = umap_local( proc_addr(vir_addr[i]->proc_nr), seg_index, vir_addr[i]->offset, bytes ); break; case REMOTE_SEG: seg_index = vir_addr[i]->segment & SEGMENT_INDEX; phys_addr[i] = umap_remote( proc_addr(vir_addr[i]->proc_nr), seg_index, vir_addr[i]->offset, bytes ); break; case BIOS_SEG: phys_addr[i] = umap_bios( proc_addr(vir_addr[i]->proc_nr), vir_addr[i]->offset, bytes ); break; case PHYS_SEG: phys_addr[i] = vir_addr[i]->offset; break; default: return(EINVAL); } /* Check if mapping succeeded. */ if (phys_addr[i] <= 0 && vir_addr[i]->segment != PHYS_SEG) return(EFAULT); } /* Now copy bytes between physical addresseses. */ phys_copy(phys_addr[_SRC_], phys_addr[_DST_], (phys_bytes) bytes); return(OK); }