/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include "cprboot.h" static int reset_input = 0; static char kbd_input[] = "keyboard input"; static char null_input[] = "\" /nulldev\" input"; /* * Ask prom to open a disk file given either the OBP device path, or the * device path representing the target drive/partition and the fs-relative * path of the file. Handle file pathnames with or without leading '/'. * if fs points to a null char, it indicates that we are opening a device. */ /* ARGSUSED */ int cpr_statefile_open(char *path, char *fs) { char full_path[OBP_MAXPATHLEN]; char *fp; int handle; int c; /* * instead of using specialstate, we use fs as the flag */ if (*fs == '\0') { /* device open */ handle = prom_open(path); /* IEEE1275 prom_open returns 0 on failure; we return -1 */ return (handle ? handle : -1); } /* * IEEE 1275 prom needs "device-path,|file-path" where * file-path can have embedded |'s. */ fp = full_path; (void) prom_strcpy(fp, fs); fp += prom_strlen(fp); *fp++ = ','; *fp++ = '|'; /* Skip a leading slash in file path -- we provided for it above. */ if (*path == '/') path++; /* Copy file path and convert separators. */ while ((c = *path++) != '\0') if (c == '/') *fp++ = '|'; else *fp++ = c; *fp = '\0'; handle = prom_open(full_path); if (verbose) { if (fp = prom_strrchr(full_path, '/')) fp++; else fp = full_path; prom_printf("cso: prom_open(\"%s\") = 0x%x\n", fp, handle); } /* * IEEE1275 prom_open returns 0 on failure; we return -1 */ return (handle ? handle : -1); } /* * Ask prom to open a disk file given the device path representing * the target drive/partition and the fs-relative path of the file. * Handle file pathnames with or without leading '/'. if fs points * to a null char, it indicates that we are opening a device. */ /* ARGSUSED */ int cpr_ufs_open(char *path, char *fs) { CB_VENTRY(cpr_ufs_open); /* * screen invalid state, then just use the other code rather than * duplicating it */ if (*fs == '\0') { /* device open */ prom_printf("cpr_ufs_open: NULL fs, path %s\n", path); return (ERR); } return (cpr_statefile_open(path, fs)); } /* * On sun4u there's no difference here, since prom groks ufs directly */ int cpr_read(int fd, caddr_t buf, size_t len) { return (prom_read(fd, buf, len, 0, 0)); } int cpr_ufs_read(int fd, caddr_t buf, int len) { return (prom_read(fd, buf, len, 0, 0)); } int cpr_ufs_close(int fd) { CB_VPRINTF(("cpr_ufs_close 0x%x\n", fd)); return (prom_close(fd)); } int cpr_statefile_close(int fd) { return (prom_close(fd)); } void cb_spin(void) { static int spindex = 0; static char *spin_pairs[] = { "|\b", "/\b", "-\b", "\\\b" }; const size_t nspin_pairs = sizeof (spin_pairs) / sizeof (spin_pairs[0]); prom_printf(spin_pairs[spindex]); spindex = (spindex + 1) % nspin_pairs; } /* * translate vaddr to phys page number */ pfn_t cpr_vatopfn(caddr_t vaddr) { physaddr_t paddr; int valid, mode; (void) prom_translate_virt(vaddr, &valid, &paddr, &mode); if (valid != -1) return (PFN_INVALID); return (paddr >> MMU_PAGESHIFT); } /* * unmap virt, then map virt to new phys; * see remap definition below */ int prom_remap(size_t size, caddr_t virt, physaddr_t phys) { ihandle_t immu; cell_t ci[8]; int rv; immu = prom_mmu_ihandle(); if (immu == (ihandle_t)-1) return (ERR); ci[0] = p1275_ptr2cell("call-method"); /* Service name */ ci[1] = (cell_t)5; /* #argument cells */ ci[2] = (cell_t)0; /* #result cells */ ci[3] = p1275_ptr2cell("remap"); /* Arg1: Method name */ ci[4] = p1275_ihandle2cell(immu); /* Arg2: memory ihandle */ ci[5] = p1275_size2cell(size); /* remap arg0 */ ci[6] = p1275_ptr2cell(virt); /* remap arg1 */ ci[7] = p1275_ull2cell_low(phys); /* remap arg2 */ promif_preprom(); rv = p1275_cif_handler(ci); promif_postprom(); if (rv) return (rv); /* Service "call-method" failed */ return (0); } /* * install remap definition in /virtual-memory node; * used for replacing a virt->phys mapping in one promif call; * this needs to be atomic from the client's perspective to * avoid faults while relocating client text. */ void install_remap(void) { static char remap_def[] = "\" /virtual-memory\" find-device " ": remap ( phys.lo virt size -- )" " 2dup unmap ( phys.lo virt size )" " 0 -rot -1 map ( ) ; " "device-end"; prom_interpret(remap_def, 0, 0, 0, 0, 0); } /* * allocate virt and phys space without any mapping; * stores virt and phys addrs at *vap and *pap */ int cb_alloc(size_t size, uint_t align, caddr_t *vap, physaddr_t *pap) { physaddr_t phys; caddr_t virt; virt = prom_allocate_virt(align, (size_t)align); if (virt == (caddr_t)-1) return (ERR); if (prom_allocate_phys(size, align, &phys) == -1) { prom_free_virt(size, virt); return (ERR); } *vap = virt; *pap = phys; return (0); } static int get_intprop(dnode_t node, caddr_t prop, void *dst) { int len, glen; len = sizeof (uint_t); glen = prom_getprop(node, prop, dst); if (glen != len) return (ERR); return (0); } /* * find cpu node for the boot processor * * sets globals: * cb_mid */ static dnode_t get_cpu_node(void) { static char *props[] = { "upa-portid", "portid", NULL }; dnode_t node; char *str, *name, **propp; uint_t cpu_id; int err; str = "get_cpu_node"; name = "cpu"; cb_mid = getmid(); for (node = prom_rootnode(); ; node = prom_nextnode(node)) { node = prom_findnode_bydevtype(node, name); if (node == OBP_NONODE) { prom_printf("\n%s: cant find node for devtype \"%s\"\n", str, name); break; } cpu_id = (uint_t)-1; for (propp = props; *propp; propp++) { err = get_intprop(node, *propp, &cpu_id); CB_VPRINTF((" cpu node 0x%x, " "prop \"%s\", cpu_id %d\n", node, *propp, (int)cpu_id)); if (err == 0) break; } if (cpu_id == cb_mid) return (node); } return (OBP_NONODE); } /* * lookup prom properties * * sets globals: * cb_dents * cb_clock_freq * cpu_delay */ int cb_get_props(void) { uint_t clock_mhz; dnode_t node; struct cb_props *cbp; static struct cb_props cpu_data[] = { "#dtlb-entries", &cb_dents, "clock-frequency", &cb_clock_freq, NULL, NULL, }; CB_VENTRY(cb_get_props); node = get_cpu_node(); if (node == OBP_NONODE) return (ERR); for (cbp = cpu_data; cbp->prop; cbp++) { if (get_intprop(node, cbp->prop, cbp->datap)) { prom_printf("\n%s: getprop error, " "node 0x%x, prop \"%s\"\n", prog, node, cbp->prop); return (ERR); } CB_VPRINTF((" \"%s\" = 0x%x\n", cbp->prop, *cbp->datap)); } /* * setup cpu_delay for cb_usec_wait */ clock_mhz = (cb_clock_freq + 500000) / 1000000; cpu_delay = clock_mhz - 7; CB_VPRINTF((" clock_mhz %d, cpu_delay %d\n", clock_mhz, cpu_delay)); return (0); } /* * map-in data pages * size should fit tte_bit.sz * rw should be 0 or TTE_HWWR_INT */ void cb_mapin(caddr_t vaddr, pfn_t ppn, uint_t size, uint_t rw, uint_t dtlb_index) { tte_t tte; tte.tte_inthi = TTE_VALID_INT | TTE_SZ_INT(size) | TTE_PFN_INTHI(ppn); tte.tte_intlo = TTE_PFN_INTLO(ppn) | TTE_LCK_INT | TTE_CP_INT | TTE_CV_INT | TTE_PRIV_INT | rw; set_dtlb_entry(dtlb_index, vaddr, &tte); } static char * prom_strstr(char *string, char *substr) { char *strp, *subp, *tmp, c; if (substr == NULL || *substr == '\0') return (string); strp = string; subp = substr; c = *subp; while (*strp) { if (*strp++ == c) { tmp = strp; while ((c = *++subp) == *strp++ && c) ; if (c == '\0') return (tmp - 1); strp = tmp; subp = substr; c = *subp; } } return (NULL); } static void cb_set_idev(char *istr) { if (reset_input) { prom_interpret(istr, 0, 0, 0, 0, 0); CB_VPRINTF(("\ncb_set_idev: reset with [%s]\n", istr)); } } /* * workaround for USB keyboard: * USB DMA activity has been known to corrupt kernel pages while cprboot * is restoring them. to quiesce the USB chip, we craft a "null" device * and temporarily use that as the prom's input device. this effectively * disables the USB keyboard until the cpr module restores the original * prom and a kernel driver re-inits and takes-over control of USB. * * may set globals: * reset_input */ int cb_usb_setup(void) { char sp[OBP_MAXPATHLEN]; static char cb_nulldev[] = { "\" /\" select-dev " "new-device " "\" nulldev\" device-name " ": read 2drop -2 ; " ": open true ; " ": close ; " ": install-abort ; " ": remove-abort ; " ": write 2drop 0 ; " ": restore ; " "finish-device " "unselect-dev" }; CB_VENTRY(cb_usb_setup); bzero(sp, sizeof (sp)); prom_interpret("stdin @ ihandle>devname swap -rot move", (uintptr_t)sp, 0, 0, 0, 0); if (prom_strstr(sp, "usb") && prom_strstr(sp, "keyboard")) { prom_interpret(cb_nulldev, 0, 0, 0, 0, 0); reset_input = 1; cb_set_idev(null_input); } return (0); } /* * switch input to keyboard before entering the prom, and switch to the * crafted nulldev after returning from the prom. this occurs only when * stdinpath is a USB keyboard; entering the prom is usually done only * for debugging purposes - see check_halt() and above DMA comment. */ void cb_enter_mon(void) { cb_set_idev(kbd_input); prom_enter_mon(); cb_set_idev(null_input); } /* * similar to above before exiting to the prom */ void cb_exit_to_mon(void) { cb_set_idev(kbd_input); prom_exit_to_mon(); }