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/*- * Copyright (c) 2000 Alfred Perlstein <alfred@freebsd.org> * Copyright (c) 2000 Paul Saab <ps@freebsd.org> * Copyright (c) 2000 John Baldwin <jhb@freebsd.org> * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/boot/i386/libi386/pxe.c 231035 2012-02-05 19:30:18Z sbruno $"); #include <stand.h> #include <string.h> #include <stdarg.h> #include <netinet/in_systm.h> #include <netinet/in.h> #include <netinet/udp.h> #include <net.h> #include <netif.h> #include <nfsv2.h> #include <iodesc.h> #include <bootp.h> #include <bootstrap.h> #include "btxv86.h" #include "pxe.h" /* * Allocate the PXE buffers statically instead of sticking grimy fingers into * BTX's private data area. The scratch buffer is used to send information to * the PXE BIOS, and the data buffer is used to receive data from the PXE BIOS. */ #define PXE_BUFFER_SIZE 0x2000 #define PXE_TFTP_BUFFER_SIZE 512 static char scratch_buffer[PXE_BUFFER_SIZE]; static char data_buffer[PXE_BUFFER_SIZE]; static pxenv_t *pxenv_p = NULL; /* PXENV+ */ static pxe_t *pxe_p = NULL; /* !PXE */ static BOOTPLAYER bootplayer; /* PXE Cached information. */ static int pxe_debug = 0; static int pxe_sock = -1; static int pxe_opens = 0; void pxe_enable(void *pxeinfo); static void (*pxe_call)(int func); static void pxenv_call(int func); static void bangpxe_call(int func); static int pxe_init(void); static int pxe_strategy(void *devdata, int flag, daddr_t dblk, size_t size, char *buf, size_t *rsize); static int pxe_open(struct open_file *f, ...); static int pxe_close(struct open_file *f); static void pxe_print(int verbose); static void pxe_cleanup(void); static void pxe_setnfshandle(char *rootpath); static void pxe_perror(int error); static int pxe_netif_match(struct netif *nif, void *machdep_hint); static int pxe_netif_probe(struct netif *nif, void *machdep_hint); static void pxe_netif_init(struct iodesc *desc, void *machdep_hint); static int pxe_netif_get(struct iodesc *desc, void *pkt, size_t len, time_t timeout); static int pxe_netif_put(struct iodesc *desc, void *pkt, size_t len); static void pxe_netif_end(struct netif *nif); extern struct netif_stats pxe_st[]; extern u_int16_t __bangpxeseg; extern u_int16_t __bangpxeoff; extern void __bangpxeentry(void); extern u_int16_t __pxenvseg; extern u_int16_t __pxenvoff; extern void __pxenventry(void); struct netif_dif pxe_ifs[] = { /* dif_unit dif_nsel dif_stats dif_private */ {0, 1, &pxe_st[0], 0} }; struct netif_stats pxe_st[NENTS(pxe_ifs)]; struct netif_driver pxenetif = { "pxenet", pxe_netif_match, pxe_netif_probe, pxe_netif_init, pxe_netif_get, pxe_netif_put, pxe_netif_end, pxe_ifs, NENTS(pxe_ifs) }; struct netif_driver *netif_drivers[] = { &pxenetif, NULL }; struct devsw pxedisk = { "pxe", DEVT_NET, pxe_init, pxe_strategy, pxe_open, pxe_close, noioctl, pxe_print, pxe_cleanup }; /* * This function is called by the loader to enable PXE support if we * are booted by PXE. The passed in pointer is a pointer to the * PXENV+ structure. */ void pxe_enable(void *pxeinfo) { pxenv_p = (pxenv_t *)pxeinfo; pxe_p = (pxe_t *)PTOV(pxenv_p->PXEPtr.segment * 16 + pxenv_p->PXEPtr.offset); pxe_call = NULL; } /* * return true if pxe structures are found/initialized, * also figures out our IP information via the pxe cached info struct */ static int pxe_init(void) { t_PXENV_GET_CACHED_INFO *gci_p; int counter; uint8_t checksum; uint8_t *checkptr; if(pxenv_p == NULL) return (0); /* look for "PXENV+" */ if (bcmp((void *)pxenv_p->Signature, S_SIZE("PXENV+"))) { pxenv_p = NULL; return (0); } /* make sure the size is something we can handle */ if (pxenv_p->Length > sizeof(*pxenv_p)) { printf("PXENV+ structure too large, ignoring\n"); pxenv_p = NULL; return (0); } /* * do byte checksum: * add up each byte in the structure, the total should be 0 */ checksum = 0; checkptr = (uint8_t *) pxenv_p; for (counter = 0; counter < pxenv_p->Length; counter++) checksum += *checkptr++; if (checksum != 0) { printf("PXENV+ structure failed checksum, ignoring\n"); pxenv_p = NULL; return (0); } /* * PXENV+ passed, so use that if !PXE is not available or * the checksum fails. */ pxe_call = pxenv_call; if (pxenv_p->Version >= 0x0200) { for (;;) { if (bcmp((void *)pxe_p->Signature, S_SIZE("!PXE"))) { pxe_p = NULL; break; } checksum = 0; checkptr = (uint8_t *)pxe_p; for (counter = 0; counter < pxe_p->StructLength; counter++) checksum += *checkptr++; if (checksum != 0) { pxe_p = NULL; break; } pxe_call = bangpxe_call; break; } } printf("\nPXE version %d.%d, real mode entry point ", (uint8_t) (pxenv_p->Version >> 8), (uint8_t) (pxenv_p->Version & 0xFF)); if (pxe_call == bangpxe_call) printf("@%04x:%04x\n", pxe_p->EntryPointSP.segment, pxe_p->EntryPointSP.offset); else printf("@%04x:%04x\n", pxenv_p->RMEntry.segment, pxenv_p->RMEntry.offset); gci_p = (t_PXENV_GET_CACHED_INFO *) scratch_buffer; bzero(gci_p, sizeof(*gci_p)); gci_p->PacketType = PXENV_PACKET_TYPE_BINL_REPLY; pxe_call(PXENV_GET_CACHED_INFO); if (gci_p->Status != 0) { pxe_perror(gci_p->Status); pxe_p = NULL; return (0); } bcopy(PTOV((gci_p->Buffer.segment << 4) + gci_p->Buffer.offset), &bootplayer, gci_p->BufferSize); return (1); } static int pxe_strategy(void *devdata, int flag, daddr_t dblk, size_t size, char *buf, size_t *rsize) { return (EIO); } static int pxe_open(struct open_file *f, ...) { va_list args; char *devname; /* Device part of file name (or NULL). */ char temp[FNAME_SIZE]; int error = 0; int i; va_start(args, f); devname = va_arg(args, char*); va_end(args); /* On first open, do netif open, mount, etc. */ if (pxe_opens == 0) { /* Find network interface. */ if (pxe_sock < 0) { pxe_sock = netif_open(devname); if (pxe_sock < 0) { printf("pxe_open: netif_open() failed\n"); return (ENXIO); } if (pxe_debug) printf("pxe_open: netif_open() succeeded\n"); } if (rootip.s_addr == 0) { /* * Do a bootp/dhcp request to find out where our * NFS/TFTP server is. Even if we dont get back * the proper information, fall back to the server * which brought us to life and a default rootpath. */ bootp(pxe_sock, BOOTP_PXE); if (rootip.s_addr == 0) rootip.s_addr = bootplayer.sip; if (!rootpath[0]) strcpy(rootpath, PXENFSROOTPATH); for (i = 0; rootpath[i] != '\0' && i < FNAME_SIZE; i++) if (rootpath[i] == ':') break; if (i && i != FNAME_SIZE && rootpath[i] == ':') { rootpath[i++] = '\0'; if (inet_addr(&rootpath[0]) != INADDR_NONE) rootip.s_addr = inet_addr(&rootpath[0]); bcopy(&rootpath[i], &temp[0], strlen(&rootpath[i])+1); bcopy(&temp[0], &rootpath[0], strlen(&rootpath[i])+1); } printf("pxe_open: server addr: %s\n", inet_ntoa(rootip)); printf("pxe_open: server path: %s\n", rootpath); printf("pxe_open: gateway ip: %s\n", inet_ntoa(gateip)); setenv("boot.netif.ip", inet_ntoa(myip), 1); setenv("boot.netif.netmask", intoa(netmask), 1); setenv("boot.netif.gateway", inet_ntoa(gateip), 1); if (bootplayer.Hardware == ETHER_TYPE) { sprintf(temp, "%6D", bootplayer.CAddr, ":"); setenv("boot.netif.hwaddr", temp, 1); } setenv("boot.nfsroot.server", inet_ntoa(rootip), 1); setenv("boot.nfsroot.path", rootpath, 1); setenv("dhcp.host-name", hostname, 1); } } pxe_opens++; f->f_devdata = &pxe_sock; return (error); } static int pxe_close(struct open_file *f) { #ifdef PXE_DEBUG if (pxe_debug) printf("pxe_close: opens=%d\n", pxe_opens); #endif /* On last close, do netif close, etc. */ f->f_devdata = NULL; /* Extra close call? */ if (pxe_opens <= 0) return (0); pxe_opens--; /* Not last close? */ if (pxe_opens > 0) return(0); #ifdef LOADER_NFS_SUPPORT /* get an NFS filehandle for our root filesystem */ pxe_setnfshandle(rootpath); #endif if (pxe_sock >= 0) { #ifdef PXE_DEBUG if (pxe_debug) printf("pxe_close: calling netif_close()\n"); #endif netif_close(pxe_sock); pxe_sock = -1; } return (0); } static void pxe_print(int verbose) { if (pxe_call != NULL) { if (*bootplayer.Sname == '\0') { printf(" "IP_STR":%s\n", IP_ARGS(htonl(bootplayer.sip)), bootplayer.bootfile); } else { printf(" %s:%s\n", bootplayer.Sname, bootplayer.bootfile); } } return; } static void pxe_cleanup(void) { #ifdef PXE_DEBUG t_PXENV_UNLOAD_STACK *unload_stack_p = (t_PXENV_UNLOAD_STACK *)scratch_buffer; t_PXENV_UNDI_SHUTDOWN *undi_shutdown_p = (t_PXENV_UNDI_SHUTDOWN *)scratch_buffer; #endif if (pxe_call == NULL) return; pxe_call(PXENV_UNDI_SHUTDOWN); #ifdef PXE_DEBUG if (pxe_debug && undi_shutdown_p->Status != 0) printf("pxe_cleanup: UNDI_SHUTDOWN failed %x\n", undi_shutdown_p->Status); #endif pxe_call(PXENV_UNLOAD_STACK); #ifdef PXE_DEBUG if (pxe_debug && unload_stack_p->Status != 0) printf("pxe_cleanup: UNLOAD_STACK failed %x\n", unload_stack_p->Status); #endif } void pxe_perror(int err) { return; } #ifdef LOADER_NFS_SUPPORT /* * Reach inside the libstand NFS code and dig out an NFS handle * for the root filesystem. */ #ifdef OLD_NFSV2 struct nfs_iodesc { struct iodesc *iodesc; off_t off; u_char fh[NFS_FHSIZE]; /* structure truncated here */ }; extern struct nfs_iodesc nfs_root_node; extern int rpc_port; static void pxe_rpcmountcall() { struct iodesc *d; int error; if (!(d = socktodesc(pxe_sock))) return; d->myport = htons(--rpc_port); d->destip = rootip; if ((error = nfs_getrootfh(d, rootpath, nfs_root_node.fh)) != 0) printf("NFS MOUNT RPC error: %d\n", error); nfs_root_node.iodesc = d; } static void pxe_setnfshandle(char *rootpath) { int i; u_char *fh; char buf[2 * NFS_FHSIZE + 3], *cp; /* * If NFS files were never opened, we need to do mount call * ourselves. Use nfs_root_node.iodesc as flag indicating * previous NFS usage. */ if (nfs_root_node.iodesc == NULL) pxe_rpcmountcall(); fh = &nfs_root_node.fh[0]; buf[0] = 'X'; cp = &buf[1]; for (i = 0; i < NFS_FHSIZE; i++, cp += 2) sprintf(cp, "%02x", fh[i]); sprintf(cp, "X"); setenv("boot.nfsroot.nfshandle", buf, 1); } #else /* !OLD_NFSV2 */ #define NFS_V3MAXFHSIZE 64 struct nfs_iodesc { struct iodesc *iodesc; off_t off; uint32_t fhsize; u_char fh[NFS_V3MAXFHSIZE]; /* structure truncated */ }; extern struct nfs_iodesc nfs_root_node; extern int rpc_port; static void pxe_rpcmountcall() { struct iodesc *d; int error; if (!(d = socktodesc(pxe_sock))) return; d->myport = htons(--rpc_port); d->destip = rootip; if ((error = nfs_getrootfh(d, rootpath, &nfs_root_node.fhsize, nfs_root_node.fh)) != 0) { printf("NFS MOUNT RPC error: %d\n", error); nfs_root_node.fhsize = 0; } nfs_root_node.iodesc = d; } static void pxe_setnfshandle(char *rootpath) { int i; u_char *fh; char buf[2 * NFS_V3MAXFHSIZE + 3], *cp; /* * If NFS files were never opened, we need to do mount call * ourselves. Use nfs_root_node.iodesc as flag indicating * previous NFS usage. */ if (nfs_root_node.iodesc == NULL) pxe_rpcmountcall(); fh = &nfs_root_node.fh[0]; buf[0] = 'X'; cp = &buf[1]; for (i = 0; i < nfs_root_node.fhsize; i++, cp += 2) sprintf(cp, "%02x", fh[i]); sprintf(cp, "X"); setenv("boot.nfsroot.nfshandle", buf, 1); sprintf(buf, "%d", nfs_root_node.fhsize); setenv("boot.nfsroot.nfshandlelen", buf, 1); } #endif /* OLD_NFSV2 */ #endif /* LOADER_NFS_SUPPORT */ void pxenv_call(int func) { #ifdef PXE_DEBUG if (pxe_debug) printf("pxenv_call %x\n", func); #endif bzero(&v86, sizeof(v86)); bzero(data_buffer, sizeof(data_buffer)); __pxenvseg = pxenv_p->RMEntry.segment; __pxenvoff = pxenv_p->RMEntry.offset; v86.ctl = V86_ADDR | V86_CALLF | V86_FLAGS; v86.es = VTOPSEG(scratch_buffer); v86.edi = VTOPOFF(scratch_buffer); v86.addr = (VTOPSEG(__pxenventry) << 16) | VTOPOFF(__pxenventry); v86.ebx = func; v86int(); v86.ctl = V86_FLAGS; } void bangpxe_call(int func) { #ifdef PXE_DEBUG if (pxe_debug) printf("bangpxe_call %x\n", func); #endif bzero(&v86, sizeof(v86)); bzero(data_buffer, sizeof(data_buffer)); __bangpxeseg = pxe_p->EntryPointSP.segment; __bangpxeoff = pxe_p->EntryPointSP.offset; v86.ctl = V86_ADDR | V86_CALLF | V86_FLAGS; v86.edx = VTOPSEG(scratch_buffer); v86.eax = VTOPOFF(scratch_buffer); v86.addr = (VTOPSEG(__bangpxeentry) << 16) | VTOPOFF(__bangpxeentry); v86.ebx = func; v86int(); v86.ctl = V86_FLAGS; } time_t getsecs() { time_t n = 0; time(&n); return n; } static int pxe_netif_match(struct netif *nif, void *machdep_hint) { return 1; } static int pxe_netif_probe(struct netif *nif, void *machdep_hint) { t_PXENV_UDP_OPEN *udpopen_p = (t_PXENV_UDP_OPEN *)scratch_buffer; if (pxe_call == NULL) return -1; bzero(udpopen_p, sizeof(*udpopen_p)); udpopen_p->src_ip = bootplayer.yip; pxe_call(PXENV_UDP_OPEN); if (udpopen_p->status != 0) { printf("pxe_netif_probe: failed %x\n", udpopen_p->status); return -1; } return 0; } static void pxe_netif_end(struct netif *nif) { t_PXENV_UDP_CLOSE *udpclose_p = (t_PXENV_UDP_CLOSE *)scratch_buffer; bzero(udpclose_p, sizeof(*udpclose_p)); pxe_call(PXENV_UDP_CLOSE); if (udpclose_p->status != 0) printf("pxe_end failed %x\n", udpclose_p->status); } static void pxe_netif_init(struct iodesc *desc, void *machdep_hint) { int i; for (i = 0; i < 6; ++i) desc->myea[i] = bootplayer.CAddr[i]; desc->xid = bootplayer.ident; } static int pxe_netif_get(struct iodesc *desc, void *pkt, size_t len, time_t timeout) { return len; } static int pxe_netif_put(struct iodesc *desc, void *pkt, size_t len) { return len; } ssize_t sendudp(struct iodesc *h, void *pkt, size_t len) { t_PXENV_UDP_WRITE *udpwrite_p = (t_PXENV_UDP_WRITE *)scratch_buffer; bzero(udpwrite_p, sizeof(*udpwrite_p)); udpwrite_p->ip = h->destip.s_addr; udpwrite_p->dst_port = h->destport; udpwrite_p->src_port = h->myport; udpwrite_p->buffer_size = len; udpwrite_p->buffer.segment = VTOPSEG(pkt); udpwrite_p->buffer.offset = VTOPOFF(pkt); if (netmask == 0 || SAMENET(myip, h->destip, netmask)) udpwrite_p->gw = 0; else udpwrite_p->gw = gateip.s_addr; pxe_call(PXENV_UDP_WRITE); #if 0 /* XXX - I dont know why we need this. */ delay(1000); #endif if (udpwrite_p->status != 0) { /* XXX: This happens a lot. It shouldn't. */ if (udpwrite_p->status != 1) printf("sendudp failed %x\n", udpwrite_p->status); return -1; } return len; } ssize_t readudp(struct iodesc *h, void *pkt, size_t len, time_t timeout) { t_PXENV_UDP_READ *udpread_p = (t_PXENV_UDP_READ *)scratch_buffer; struct udphdr *uh = NULL; uh = (struct udphdr *) pkt - 1; bzero(udpread_p, sizeof(*udpread_p)); udpread_p->dest_ip = h->myip.s_addr; udpread_p->d_port = h->myport; udpread_p->buffer_size = len; udpread_p->buffer.segment = VTOPSEG(data_buffer); udpread_p->buffer.offset = VTOPOFF(data_buffer); pxe_call(PXENV_UDP_READ); #if 0 /* XXX - I dont know why we need this. */ delay(1000); #endif if (udpread_p->status != 0) { /* XXX: This happens a lot. It shouldn't. */ if (udpread_p->status != 1) printf("readudp failed %x\n", udpread_p->status); return -1; } bcopy(data_buffer, pkt, udpread_p->buffer_size); uh->uh_sport = udpread_p->s_port; return udpread_p->buffer_size; }