2 * Copyright (c) 2006 The DragonFly Project. All rights reserved.
4 * This code is derived from software contributed to The DragonFly Project
5 * by Matthew Dillon <dillon@backplane.com>
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in
15 * the documentation and/or other materials provided with the
17 * 3. Neither the name of The DragonFly Project nor the names of its
18 * contributors may be used to endorse or promote products derived
19 * from this software without specific, prior written permission.
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
22 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
23 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
24 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
25 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
26 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING,
27 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
28 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
29 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
30 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
31 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
34 * $DragonFly: src/sys/platform/vkernel/platform/init.c,v 1.56 2008/05/27 07:48:00 dillon Exp $
37 #include <sys/types.h>
38 #include <sys/systm.h>
39 #include <sys/kernel.h>
43 #include <sys/random.h>
44 #include <sys/vkernel.h>
46 #include <sys/reboot.h>
48 #include <sys/msgbuf.h>
49 #include <sys/vmspace.h>
50 #include <sys/socket.h>
51 #include <sys/sockio.h>
52 #include <sys/sysctl.h>
54 #include <vm/vm_page.h>
55 #include <sys/mplock2.h>
57 #include <machine/cpu.h>
58 #include <machine/globaldata.h>
59 #include <machine/tls.h>
60 #include <machine/md_var.h>
61 #include <machine/vmparam.h>
62 #include <cpu/specialreg.h>
65 #include <net/if_arp.h>
66 #include <net/ethernet.h>
67 #include <net/bridge/if_bridgevar.h>
68 #include <netinet/in.h>
69 #include <arpa/inet.h>
83 vm_paddr_t phys_avail[16];
85 vm_paddr_t Maxmem_bytes;
88 struct vkdisk_info DiskInfo[VKDISK_MAX];
90 struct vknetif_info NetifInfo[VKNETIF_MAX];
96 vm_offset_t virtual_start;
97 vm_offset_t virtual_end;
98 vm_offset_t virtual2_start;
99 vm_offset_t virtual2_end;
100 vm_offset_t kernel_vm_end;
101 vm_offset_t crashdumpmap;
102 vm_offset_t clean_sva;
103 vm_offset_t clean_eva;
104 struct msgbuf *msgbufp;
107 vpte_t *KernelPTA; /* Warning: Offset for direct VA translation */
108 u_int cpu_feature; /* XXX */
110 int64_t tsc_frequency;
111 int optcpus; /* number of cpus - see mp_start() */
112 int lwp_cpu_lock; /* if/how to lock virtual CPUs to real CPUs */
113 int real_ncpus; /* number of real CPUs */
114 int next_cpu; /* next real CPU to lock a virtual CPU to */
116 int via_feature_xcrypt = 0; /* XXX */
117 int via_feature_rng = 0; /* XXX */
119 struct privatespace *CPU_prvspace;
121 static struct trapframe proc0_tf;
122 static void *proc0paddr;
124 static void init_sys_memory(char *imageFile);
125 static void init_kern_memory(void);
126 static void init_globaldata(void);
127 static void init_vkernel(void);
128 static void init_disk(char *diskExp[], int diskFileNum, enum vkdisk_type type);
129 static void init_netif(char *netifExp[], int netifFileNum);
130 static void writepid(void);
131 static void cleanpid(void);
132 static int unix_connect(const char *path);
133 static void usage_err(const char *ctl, ...);
134 static void usage_help(_Bool);
137 static char **save_av;
140 * Kernel startup for virtual kernels - standard main()
143 main(int ac, char **av)
145 char *memImageFile = NULL;
146 char *netifFile[VKNETIF_MAX];
147 char *diskFile[VKDISK_MAX];
148 char *cdFile[VKDISK_MAX];
152 int netifFileNum = 0;
155 int bootOnDisk = -1; /* set below to vcd (0) or vkd (1) */
163 int real_vkernel_enable;
178 kernel_mem_readonly = 1;
182 lwp_cpu_lock = LCL_NONE;
184 real_vkernel_enable = 0;
185 vsize = sizeof(real_vkernel_enable);
186 sysctlbyname("vm.vkernel_enable", &real_vkernel_enable, &vsize, NULL,0);
188 if (real_vkernel_enable == 0) {
189 errx(1, "vm.vkernel_enable is 0, must be set "
190 "to 1 to execute a vkernel!");
194 vsize = sizeof(real_ncpus);
195 sysctlbyname("hw.ncpu", &real_ncpus, &vsize, NULL, 0);
200 while ((c = getopt(ac, av, "c:hsvl:m:n:r:e:i:p:I:U")) != -1) {
204 * name=value:name=value:name=value...
207 * Allow values to be quoted but note that shells
208 * may remove the quotes, so using this feature
209 * to embed colons may require a backslash.
216 kern_envp = malloc(kenv_size);
217 if (kern_envp == NULL)
218 errx(1, "Couldn't allocate %zd bytes for kern_envp", kenv_size);
220 kenv_size2 = kenv_size + n + 1;
222 if ((tmp = realloc(kern_envp, kenv_size2)) == NULL)
223 errx(1, "Couldn't reallocate %zd bytes for kern_envp", kenv_size2);
225 kenv_size = kenv_size2;
228 for (i = 0, j = pos; i < n; ++i) {
229 if (optarg[i] == '"')
231 else if (optarg[i] == '\'')
233 else if (isq == 0 && optarg[i] == ':')
236 kern_envp[j++] = optarg[i];
243 boothowto |= RB_SINGLE;
249 memImageFile = optarg;
252 if (netifFileNum < VKNETIF_MAX)
253 netifFile[netifFileNum++] = strdup(optarg);
258 if (diskFileNum + cdFileNum < VKDISK_MAX)
259 diskFile[diskFileNum++] = strdup(optarg);
264 if (diskFileNum + cdFileNum < VKDISK_MAX)
265 cdFile[cdFileNum++] = strdup(optarg);
268 Maxmem_bytes = strtoull(optarg, &suffix, 0);
285 usage_err("Bad maxmem option");
293 if (strncmp("map", optarg, 3) == 0) {
294 lwp_cpu_lock = LCL_PER_CPU;
295 if (optarg[3] == ',') {
296 next_cpu = strtol(optarg+4, &endp, 0);
298 usage_err("Bad target CPU number at '%s'", endp);
302 if (next_cpu < 0 || next_cpu > real_ncpus - 1)
303 usage_err("Bad target CPU, valid range is 0-%d", real_ncpus - 1);
304 } else if (strncmp("any", optarg, 3) == 0) {
305 lwp_cpu_lock = LCL_NONE;
307 lwp_cpu_lock = LCL_SINGLE_CPU;
308 next_cpu = strtol(optarg, &endp, 0);
310 usage_err("Bad target CPU number at '%s'", endp);
311 if (next_cpu < 0 || next_cpu > real_ncpus - 1)
312 usage_err("Bad target CPU, valid range is 0-%d", real_ncpus - 1);
317 * This value is set up by mp_start(), don't just
321 optcpus = strtol(optarg, NULL, 0);
322 if (optcpus < 1 || optcpus > MAXCPU)
323 usage_err("Bad ncpus, valid range is 1-%d", MAXCPU);
325 if (strtol(optarg, NULL, 0) != 1) {
326 usage_err("You built a UP vkernel, only 1 cpu!");
335 kernel_mem_readonly = 0;
347 init_sys_memory(memImageFile);
359 vsize = sizeof(tsc_present);
360 sysctlbyname("hw.tsc_present", &tsc_present, &vsize, NULL, 0);
361 vsize = sizeof(tsc_frequency);
362 sysctlbyname("hw.tsc_frequency", &tsc_frequency, &vsize, NULL, 0);
364 cpu_feature |= CPUID_TSC;
369 vsize = sizeof(supports_sse);
371 sysctlbyname("hw.instruction_sse", &supports_sse, &vsize, NULL, 0);
372 init_fpu(supports_sse);
374 cpu_feature |= CPUID_SSE | CPUID_FXSR;
377 * We boot from the first installed disk.
379 if (bootOnDisk == 1) {
380 init_disk(diskFile, diskFileNum, VKD_DISK);
381 init_disk(cdFile, cdFileNum, VKD_CD);
383 init_disk(cdFile, cdFileNum, VKD_CD);
384 init_disk(diskFile, diskFileNum, VKD_DISK);
386 init_netif(netifFile, netifFileNum);
394 * Initialize system memory. This is the virtual kernel's 'RAM'.
398 init_sys_memory(char *imageFile)
405 * Figure out the system memory image size. If an image file was
406 * specified and -m was not specified, use the image file's size.
408 if (imageFile && stat(imageFile, &st) == 0 && Maxmem_bytes == 0)
409 Maxmem_bytes = (vm_paddr_t)st.st_size;
410 if ((imageFile == NULL || stat(imageFile, &st) < 0) &&
412 errx(1, "Cannot create new memory file %s unless "
413 "system memory size is specified with -m",
419 * Maxmem must be known at this time
421 if (Maxmem_bytes < 32 * 1024 * 1024 || (Maxmem_bytes & SEG_MASK)) {
422 errx(1, "Bad maxmem specification: 32MB minimum, "
423 "multiples of %dMB only",
424 SEG_SIZE / 1024 / 1024);
429 * Generate an image file name if necessary, then open/create the
430 * file exclusively locked. Do not allow multiple virtual kernels
431 * to use the same image file.
433 * Don't iterate through a million files if we do not have write
434 * access to the directory, stop if our open() failed on a
435 * non-existant file. Otherwise opens can fail for any number
436 * of reasons (lock failed, file not owned or writable by us, etc).
438 if (imageFile == NULL) {
439 for (i = 0; i < 1000000; ++i) {
440 asprintf(&imageFile, "/var/vkernel/memimg.%06d", i);
442 O_RDWR|O_CREAT|O_EXLOCK|O_NONBLOCK, 0644);
443 if (fd < 0 && stat(imageFile, &st) == 0) {
450 fd = open(imageFile, O_RDWR|O_CREAT|O_EXLOCK|O_NONBLOCK, 0644);
452 printf("Using memory file: %s\n", imageFile);
453 if (fd < 0 || fstat(fd, &st) < 0) {
454 err(1, "Unable to open/create %s", imageFile);
459 * Truncate or extend the file as necessary. Clean out the contents
460 * of the file, we want it to be full of holes so we don't waste
461 * time reading in data from an old file that we no longer care
465 ftruncate(fd, Maxmem_bytes);
468 Maxmem = Maxmem_bytes >> PAGE_SHIFT;
473 * Initialize kernel memory. This reserves kernel virtual memory by using
479 init_kern_memory(void)
485 char *topofstack = &dummy;
490 * Memory map our kernel virtual memory space. Note that the
491 * kernel image itself is not made part of this memory for the
494 * The memory map must be segment-aligned so we can properly
497 * If the system kernel has a different MAXDSIZ, it might not
498 * be possible to map kernel memory in its prefered location.
499 * Try a number of different locations.
501 try = (void *)0x40000000;
503 while ((char *)try + KERNEL_KVA_SIZE < topofstack) {
504 base = mmap(try, KERNEL_KVA_SIZE, PROT_READ|PROT_WRITE,
505 MAP_FILE|MAP_SHARED|MAP_VPAGETABLE,
509 if (base != MAP_FAILED)
510 munmap(base, KERNEL_KVA_SIZE);
511 try = (char *)try + 0x10000000;
514 err(1, "Unable to mmap() kernel virtual memory!");
517 madvise(base, KERNEL_KVA_SIZE, MADV_NOSYNC);
518 KvaStart = (vm_offset_t)base;
519 KvaSize = KERNEL_KVA_SIZE;
520 KvaEnd = KvaStart + KvaSize;
522 /* cannot use kprintf yet */
523 printf("KVM mapped at %p-%p\n", (void *)KvaStart, (void *)KvaEnd);
526 * Create a top-level page table self-mapping itself.
528 * Initialize the page directory at physical page index 0 to point
529 * to an array of page table pages starting at physical page index 1
531 lseek(MemImageFd, 0L, 0);
532 for (i = 0; i < KERNEL_KVA_SIZE / SEG_SIZE; ++i) {
533 pte = ((i + 1) * PAGE_SIZE) | VPTE_V | VPTE_R | VPTE_W;
534 write(MemImageFd, &pte, sizeof(pte));
538 * Initialize the PTEs in the page table pages required to map the
539 * page table itself. This includes mapping the page directory page
540 * at the base so we go one more loop then normal.
542 lseek(MemImageFd, PAGE_SIZE, 0);
543 for (i = 0; i <= KERNEL_KVA_SIZE / SEG_SIZE * sizeof(vpte_t); ++i) {
544 pte = (i * PAGE_SIZE) | VPTE_V | VPTE_R | VPTE_W;
545 write(MemImageFd, &pte, sizeof(pte));
549 * Initialize remaining PTEs to 0. We may be reusing a memory image
550 * file. This is approximately a megabyte.
552 i = (KERNEL_KVA_SIZE / PAGE_SIZE - i) * sizeof(pte);
553 zero = malloc(PAGE_SIZE);
554 bzero(zero, PAGE_SIZE);
556 write(MemImageFd, zero, (i > PAGE_SIZE) ? PAGE_SIZE : i);
557 i = i - ((i > PAGE_SIZE) ? PAGE_SIZE : i);
562 * Enable the page table and calculate pointers to our self-map
563 * for easy kernel page table manipulation.
565 * KernelPTA must be offset so we can do direct VA translations
567 mcontrol(base, KERNEL_KVA_SIZE, MADV_SETMAP,
568 0 | VPTE_R | VPTE_W | VPTE_V);
569 KernelPTD = (vpte_t *)base; /* pg directory */
570 KernelPTA = (vpte_t *)((char *)base + PAGE_SIZE); /* pg table pages */
571 KernelPTA -= KvaStart >> PAGE_SHIFT;
574 * phys_avail[] represents unallocated physical memory. MI code
575 * will use phys_avail[] to create the vm_page array.
577 phys_avail[0] = PAGE_SIZE +
578 KERNEL_KVA_SIZE / PAGE_SIZE * sizeof(vpte_t);
579 phys_avail[0] = (phys_avail[0] + PAGE_MASK) & ~(vm_paddr_t)PAGE_MASK;
580 phys_avail[1] = Maxmem_bytes;
583 * (virtual_start, virtual_end) represent unallocated kernel virtual
584 * memory. MI code will create kernel_map using these parameters.
586 virtual_start = KvaStart + PAGE_SIZE +
587 KERNEL_KVA_SIZE / PAGE_SIZE * sizeof(vpte_t);
588 virtual_start = (virtual_start + PAGE_MASK) & ~(vm_offset_t)PAGE_MASK;
589 virtual_end = KvaStart + KERNEL_KVA_SIZE;
592 * kernel_vm_end could be set to virtual_end but we want some
593 * indication of how much of the kernel_map we've used, so
594 * set it low and let pmap_growkernel increase it even though we
595 * don't need to create any new page table pages.
597 kernel_vm_end = virtual_start;
600 * Allocate space for process 0's UAREA.
602 proc0paddr = (void *)virtual_start;
603 for (i = 0; i < UPAGES; ++i) {
604 pmap_kenter_quick(virtual_start, phys_avail[0]);
605 virtual_start += PAGE_SIZE;
606 phys_avail[0] += PAGE_SIZE;
612 crashdumpmap = virtual_start;
613 virtual_start += MAXDUMPPGS * PAGE_SIZE;
616 * msgbufp maps the system message buffer
618 assert((MSGBUF_SIZE & PAGE_MASK) == 0);
619 msgbufp = (void *)virtual_start;
620 for (i = 0; i < (MSGBUF_SIZE >> PAGE_SHIFT); ++i) {
621 pmap_kenter_quick(virtual_start, phys_avail[0]);
622 virtual_start += PAGE_SIZE;
623 phys_avail[0] += PAGE_SIZE;
625 msgbufinit(msgbufp, MSGBUF_SIZE);
628 * used by kern_memio for /dev/mem access
630 ptvmmap = (caddr_t)virtual_start;
631 virtual_start += PAGE_SIZE;
634 * Bootstrap the kernel_pmap
640 * Map the per-cpu globaldata for cpu #0. Allocate the space using
641 * virtual_start and phys_avail[0]
645 init_globaldata(void)
652 * Reserve enough KVA to cover possible cpus. This is a considerable
653 * amount of KVA since the privatespace structure includes two
654 * whole page table mappings.
656 virtual_start = (virtual_start + SEG_MASK) & ~(vm_offset_t)SEG_MASK;
657 CPU_prvspace = (void *)virtual_start;
658 virtual_start += sizeof(struct privatespace) * SMP_MAXCPU;
661 * Allocate enough physical memory to cover the mdglobaldata
662 * portion of the space and the idle stack and map the pages
663 * into KVA. For cpu #0 only.
665 for (i = 0; i < sizeof(struct mdglobaldata); i += PAGE_SIZE) {
667 va = (vm_offset_t)&CPU_prvspace[0].mdglobaldata + i;
668 pmap_kenter_quick(va, pa);
669 phys_avail[0] += PAGE_SIZE;
671 for (i = 0; i < sizeof(CPU_prvspace[0].idlestack); i += PAGE_SIZE) {
673 va = (vm_offset_t)&CPU_prvspace[0].idlestack + i;
674 pmap_kenter_quick(va, pa);
675 phys_avail[0] += PAGE_SIZE;
679 * Setup the %fs for cpu #0. The mycpu macro works after this
680 * point. Note that %gs is used by pthreads.
682 tls_set_fs(&CPU_prvspace[0], sizeof(struct privatespace));
686 * Initialize very low level systems including thread0, proc0, etc.
692 struct mdglobaldata *gd;
694 gd = &CPU_prvspace[0].mdglobaldata;
695 bzero(gd, sizeof(*gd));
697 gd->mi.gd_curthread = &thread0;
698 thread0.td_gd = &gd->mi;
700 ncpus2 = 1; /* rounded down power of 2 */
701 ncpus_fit = 1; /* rounded up power of 2 */
702 /* ncpus2_mask and ncpus_fit_mask are 0 */
704 gd->mi.gd_prvspace = &CPU_prvspace[0];
705 mi_gdinit(&gd->mi, 0);
707 mi_proc0init(&gd->mi, proc0paddr);
708 lwp0.lwp_md.md_regs = &proc0_tf;
713 * Get the initial mplock with a count of 1 for the BSP.
714 * This uses a LOGICAL cpu ID, ie BSP == 0.
716 cpu_get_initial_mplock();
720 #if 0 /* #ifdef DDB */
722 if (boothowto & RB_KDB)
723 Debugger("Boot flags requested debugger");
727 initializecpu(); /* Initialize CPU registers */
729 init_param2((phys_avail[1] - phys_avail[0]) / PAGE_SIZE);
733 * Map the message buffer
735 for (off = 0; off < round_page(MSGBUF_SIZE); off += PAGE_SIZE)
736 pmap_kenter((vm_offset_t)msgbufp + off, avail_end + off);
737 msgbufinit(msgbufp, MSGBUF_SIZE);
740 thread0.td_pcb_cr3 ... MMU
741 lwp0.lwp_md.md_regs = &proc0_tf;
746 * Filesystem image paths for the virtual kernel are optional.
747 * If specified they each should point to a disk image,
748 * the first of which will become the root disk.
750 * The virtual kernel caches data from our 'disk' just like a normal kernel,
751 * so we do not really want the real kernel to cache the data too. Use
752 * O_DIRECT to remove the duplication.
756 init_disk(char *diskExp[], int diskFileNum, enum vkdisk_type type)
760 if (diskFileNum == 0)
763 for(i=0; i < diskFileNum; i++){
768 warnx("Invalid argument to '-r'");
772 if (DiskNum < VKDISK_MAX) {
774 struct vkdisk_info* info = NULL;
778 if (type == VKD_DISK)
779 fd = open(fname, O_RDWR|O_DIRECT, 0644);
781 fd = open(fname, O_RDONLY|O_DIRECT, 0644);
782 if (fd < 0 || fstat(fd, &st) < 0) {
783 err(1, "Unable to open/create %s", fname);
786 if (S_ISREG(st.st_mode)) {
787 if (flock(fd, LOCK_EX|LOCK_NB) < 0) {
788 errx(1, "Disk image %s is already "
794 info = &DiskInfo[DiskNum];
800 memcpy(info->fname, fname, l);
803 if (type == VKD_CD) {
804 rootdevnames[0] = "cd9660:vcd0a";
805 } else if (type == VKD_DISK) {
806 rootdevnames[0] = "ufs:vkd0s0a";
807 rootdevnames[1] = "ufs:vkd0s1a";
813 warnx("vkd%d (%s) > VKDISK_MAX", DiskNum, fname);
821 netif_set_tapflags(int tap_unit, int f, int s)
826 bzero(&ifr, sizeof(ifr));
828 snprintf(ifr.ifr_name, sizeof(ifr.ifr_name), "tap%d", tap_unit);
829 if (ioctl(s, SIOCGIFFLAGS, &ifr) < 0) {
830 warn("tap%d: ioctl(SIOCGIFFLAGS) failed", tap_unit);
837 * If the flags are already set/cleared, then we return
838 * immediately to avoid extra syscalls
840 flags = (ifr.ifr_flags & 0xffff) | (ifr.ifr_flagshigh << 16);
844 if ((flags & f) == 0)
855 * Fix up ifreq.ifr_name, since it may be trashed
856 * in previous ioctl(SIOCGIFFLAGS)
858 snprintf(ifr.ifr_name, sizeof(ifr.ifr_name), "tap%d", tap_unit);
860 ifr.ifr_flags = flags & 0xffff;
861 ifr.ifr_flagshigh = flags >> 16;
862 if (ioctl(s, SIOCSIFFLAGS, &ifr) < 0) {
863 warn("tap%d: ioctl(SIOCSIFFLAGS) failed", tap_unit);
871 netif_set_tapaddr(int tap_unit, in_addr_t addr, in_addr_t mask, int s)
873 struct ifaliasreq ifra;
874 struct sockaddr_in *in;
876 bzero(&ifra, sizeof(ifra));
877 snprintf(ifra.ifra_name, sizeof(ifra.ifra_name), "tap%d", tap_unit);
880 in = (struct sockaddr_in *)&ifra.ifra_addr;
881 in->sin_family = AF_INET;
882 in->sin_len = sizeof(*in);
883 in->sin_addr.s_addr = addr;
887 in = (struct sockaddr_in *)&ifra.ifra_mask;
888 in->sin_len = sizeof(*in);
889 in->sin_addr.s_addr = mask;
892 if (ioctl(s, SIOCAIFADDR, &ifra) < 0) {
893 warn("tap%d: ioctl(SIOCAIFADDR) failed", tap_unit);
901 netif_add_tap2brg(int tap_unit, const char *ifbridge, int s)
906 bzero(&ifbr, sizeof(ifbr));
907 snprintf(ifbr.ifbr_ifsname, sizeof(ifbr.ifbr_ifsname),
910 bzero(&ifd, sizeof(ifd));
911 strlcpy(ifd.ifd_name, ifbridge, sizeof(ifd.ifd_name));
912 ifd.ifd_cmd = BRDGADD;
913 ifd.ifd_len = sizeof(ifbr);
914 ifd.ifd_data = &ifbr;
916 if (ioctl(s, SIOCSDRVSPEC, &ifd) < 0) {
918 * 'errno == EEXIST' means that the tap(4) is already
919 * a member of the bridge(4)
921 if (errno != EEXIST) {
922 warn("ioctl(%s, SIOCSDRVSPEC) failed", ifbridge);
929 #define TAPDEV_OFLAGS (O_RDWR | O_NONBLOCK)
932 * Locate the first unused tap(4) device file if auto mode is requested,
933 * or open the user supplied device file, and bring up the corresponding
936 * NOTE: Only tap(4) device file is supported currently
940 netif_open_tap(const char *netif, int *tap_unit, int s)
942 char tap_dev[MAXPATHLEN];
949 if (strcmp(netif, "auto") == 0) {
951 * Find first unused tap(4) device file
953 tap_fd = open("/dev/tap", TAPDEV_OFLAGS);
955 warnc(errno, "Unable to find a free tap(4)");
960 * User supplied tap(4) device file or unix socket.
962 if (netif[0] == '/') /* Absolute path */
963 strlcpy(tap_dev, netif, sizeof(tap_dev));
965 snprintf(tap_dev, sizeof(tap_dev), "/dev/%s", netif);
967 tap_fd = open(tap_dev, TAPDEV_OFLAGS);
970 * If we cannot open normally try to connect to it.
973 tap_fd = unix_connect(tap_dev);
976 warn("Unable to open %s", tap_dev);
982 * Check whether the device file is a tap(4)
984 if (fstat(tap_fd, &st) < 0) {
986 } else if (S_ISCHR(st.st_mode)) {
987 dname = fdevname(tap_fd);
989 dname = strstr(dname, "tap");
992 * Bring up the corresponding tap(4) interface
994 *tap_unit = strtol(dname + 3, NULL, 10);
995 printf("TAP UNIT %d\n", *tap_unit);
996 if (netif_set_tapflags(*tap_unit, IFF_UP, s) == 0)
1003 } else if (S_ISSOCK(st.st_mode)) {
1005 * Special socket connection (typically to vknet). We
1006 * do not have to do anything.
1014 warnx("%s is not a tap(4) device or socket", tap_dev);
1023 unix_connect(const char *path)
1025 struct sockaddr_un sunx;
1028 int sndbuf = 262144;
1031 snprintf(sunx.sun_path, sizeof(sunx.sun_path), "%s", path);
1032 len = offsetof(struct sockaddr_un, sun_path[strlen(sunx.sun_path)]);
1033 ++len; /* include nul */
1034 sunx.sun_family = AF_UNIX;
1037 net_fd = socket(AF_UNIX, SOCK_SEQPACKET, 0);
1040 if (connect(net_fd, (void *)&sunx, len) < 0) {
1044 setsockopt(net_fd, SOL_SOCKET, SO_SNDBUF, &sndbuf, sizeof(sndbuf));
1045 if (fstat(net_fd, &st) == 0)
1046 printf("Network socket buffer: %d bytes\n", st.st_blksize);
1047 fcntl(net_fd, F_SETFL, O_NONBLOCK);
1053 #undef TAPDEV_OFLAGS
1056 * Following syntax is supported,
1057 * 1) x.x.x.x tap(4)'s address is x.x.x.x
1059 * 2) x.x.x.x/z tap(4)'s address is x.x.x.x
1060 * tap(4)'s netmask len is z
1062 * 3) x.x.x.x:y.y.y.y tap(4)'s address is x.x.x.x
1063 * pseudo netif's address is y.y.y.y
1065 * 4) x.x.x.x:y.y.y.y/z tap(4)'s address is x.x.x.x
1066 * pseudo netif's address is y.y.y.y
1067 * tap(4) and pseudo netif's netmask len are z
1069 * 5) bridgeX tap(4) will be added to bridgeX
1071 * 6) bridgeX:y.y.y.y tap(4) will be added to bridgeX
1072 * pseudo netif's address is y.y.y.y
1074 * 7) bridgeX:y.y.y.y/z tap(4) will be added to bridgeX
1075 * pseudo netif's address is y.y.y.y
1076 * pseudo netif's netmask len is z
1080 netif_init_tap(int tap_unit, in_addr_t *addr, in_addr_t *mask, int s)
1082 in_addr_t tap_addr, netmask, netif_addr;
1083 int next_netif_addr;
1084 char *tok, *masklen_str, *ifbridge;
1089 tok = strtok(NULL, ":/");
1092 * Nothing special, simply use tap(4) as backend
1097 if (inet_pton(AF_INET, tok, &tap_addr) > 0) {
1099 * tap(4)'s address is supplied
1104 * If there is next token, then it may be pseudo
1105 * netif's address or netmask len for tap(4)
1107 next_netif_addr = 0;
1110 * Not tap(4)'s address, assume it as a bridge(4)
1117 * If there is next token, then it must be pseudo
1120 next_netif_addr = 1;
1123 netmask = netif_addr = 0;
1125 tok = strtok(NULL, ":/");
1129 if (inet_pton(AF_INET, tok, &netif_addr) <= 0) {
1130 if (next_netif_addr) {
1131 warnx("Invalid pseudo netif address: %s", tok);
1137 * Current token is not address, then it must be netmask len
1142 * Current token is pseudo netif address, if there is next token
1143 * it must be netmask len
1145 masklen_str = strtok(NULL, "/");
1148 /* Calculate netmask */
1149 if (masklen_str != NULL) {
1152 masklen = strtoul(masklen_str, NULL, 10);
1153 if (masklen < 32 && masklen > 0) {
1154 netmask = htonl(~((1LL << (32 - masklen)) - 1)
1157 warnx("Invalid netmask len: %lu", masklen);
1162 /* Make sure there is no more token left */
1163 if (strtok(NULL, ":/") != NULL) {
1164 warnx("Invalid argument to '-I'");
1171 } else if (ifbridge == NULL) {
1172 /* Set tap(4) address/netmask */
1173 if (netif_set_tapaddr(tap_unit, tap_addr, netmask, s) < 0)
1176 /* Tie tap(4) to bridge(4) */
1177 if (netif_add_tap2brg(tap_unit, ifbridge, s) < 0)
1187 * NetifInfo[] will be filled for pseudo netif initialization.
1188 * NetifNum will be bumped to reflect the number of valid entries
1193 init_netif(char *netifExp[], int netifExpNum)
1197 if (netifExpNum == 0)
1200 s = socket(AF_INET, SOCK_DGRAM, 0); /* for ioctl(SIOC) */
1204 for (i = 0; i < netifExpNum; ++i) {
1205 struct vknetif_info *info;
1206 in_addr_t netif_addr, netif_mask;
1207 int tap_fd, tap_unit;
1210 netif = strtok(netifExp[i], ":");
1211 if (netif == NULL) {
1212 warnx("Invalid argument to '-I'");
1217 * Open tap(4) device file and bring up the
1218 * corresponding interface
1220 tap_fd = netif_open_tap(netif, &tap_unit, s);
1225 * Initialize tap(4) and get address/netmask
1228 * NB: Rest part of netifExp[i] is passed
1229 * to netif_init_tap() implicitly.
1231 if (netif_init_tap(tap_unit, &netif_addr, &netif_mask, s) < 0) {
1233 * NB: Closing tap(4) device file will bring
1234 * down the corresponding interface
1240 info = &NetifInfo[NetifNum];
1241 info->tap_fd = tap_fd;
1242 info->tap_unit = tap_unit;
1243 info->netif_addr = netif_addr;
1244 info->netif_mask = netif_mask;
1247 if (NetifNum >= VKNETIF_MAX) /* XXX will this happen? */
1254 * Create the pid file and leave it open and locked while the vkernel is
1255 * running. This allows a script to use /usr/bin/lockf to probe whether
1256 * a vkernel is still running (so as not to accidently kill an unrelated
1257 * process from a stale pid file).
1266 if (pid_file != NULL) {
1267 snprintf(buf, sizeof(buf), "%ld\n", (long)getpid());
1268 fd = open(pid_file, O_RDWR|O_CREAT|O_EXLOCK|O_NONBLOCK, 0666);
1270 if (errno == EWOULDBLOCK) {
1271 perror("Failed to lock pidfile, "
1272 "vkernel already running");
1274 perror("Failed to create pidfile");
1279 write(fd, buf, strlen(buf));
1280 /* leave the file open to maintain the lock */
1288 if (pid_file != NULL) {
1289 if (unlink(pid_file) < 0)
1290 perror("Warning: couldn't remove pidfile");
1296 usage_err(const char *ctl, ...)
1301 vfprintf(stderr, ctl, va);
1303 fprintf(stderr, "\n");
1309 usage_help(_Bool help)
1311 fprintf(stderr, "Usage: %s [-hsUv] [-c file] [-e name=value:name=value:...]\n"
1312 "\t[-i file] [-I interface[:address1[:address2][/netmask]]] [-l cpulock]\n"
1313 "\t[-m size] [-n numcpus] [-p file] [-r file]\n", save_av[0]);
1316 fprintf(stderr, "\nArguments:\n"
1317 "\t-c\tSpecify a readonly CD-ROM image file to be used by the kernel.\n"
1318 "\t-e\tSpecify an environment to be used by the kernel.\n"
1319 "\t-h\tThis list of options.\n"
1320 "\t-i\tSpecify a memory image file to be used by the virtual kernel.\n"
1321 "\t-I\tCreate a virtual network device.\n"
1322 "\t-l\tSpecify which, if any, real CPUs to lock virtual CPUs to.\n"
1323 "\t-m\tSpecify the amount of memory to be used by the kernel in bytes.\n"
1324 "\t-n\tSpecify the number of CPUs you wish to emulate.\n"
1325 "\t-p\tSpecify a file in which to store the process ID.\n"
1326 "\t-r\tSpecify a R/W disk image file to be used by the kernel.\n"
1327 "\t-s\tBoot into single-user mode.\n"
1328 "\t-U\tEnable writing to kernel memory and module loading.\n"
1329 "\t-v\tTurn on verbose booting.\n");
1337 kprintf("cpu reset, rebooting vkernel\n");
1340 execv(save_av[0], save_av);
1346 kprintf("cpu halt, exiting vkernel\n");
1354 switch(lwp_cpu_lock) {
1357 kprintf("Locking CPU%d to real cpu %d\n",
1359 usched_set(getpid(), USCHED_SET_CPU, &next_cpu, sizeof(next_cpu));
1361 if (next_cpu >= real_ncpus)
1364 case LCL_SINGLE_CPU:
1366 kprintf("Locking CPU%d to real cpu %d\n",
1368 usched_set(getpid(), USCHED_SET_CPU, &next_cpu, sizeof(next_cpu));
1371 /* do not map virtual cpus to real cpus */