/* * 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" /* * Platform specific implementation code */ #define SUNDDI_IMPL #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern void cpr_clear_bitmaps(void); extern void dtlb_wr_entry(uint_t, tte_t *, uint64_t *); extern void itlb_wr_entry(uint_t, tte_t *, uint64_t *); static int i_cpr_storage_desc_alloc(csd_t **, pgcnt_t *, csd_t **, int); static void i_cpr_storage_desc_init(csd_t *, pgcnt_t, csd_t *); static caddr_t i_cpr_storage_data_alloc(pgcnt_t, pgcnt_t *, int); static int cpr_dump_sensitive(vnode_t *, csd_t *); static void i_cpr_clear_entries(uint64_t, uint64_t); static void i_cpr_xcall(xcfunc_t); void i_cpr_storage_free(void); extern void *i_cpr_data_page; extern int cpr_test_mode; extern int cpr_nbitmaps; extern char cpr_default_path[]; extern caddr_t textva, datava; static struct cpr_map_info cpr_prom_retain[CPR_PROM_RETAIN_CNT]; caddr_t cpr_vaddr = NULL; static uint_t sensitive_pages_saved; static uint_t sensitive_size_saved; caddr_t i_cpr_storage_data_base; caddr_t i_cpr_storage_data_end; csd_t *i_cpr_storage_desc_base; csd_t *i_cpr_storage_desc_end; /* one byte beyond last used descp */ csd_t *i_cpr_storage_desc_last_used; /* last used descriptor */ caddr_t sensitive_write_ptr; /* position for next storage write */ size_t i_cpr_sensitive_bytes_dumped; pgcnt_t i_cpr_sensitive_pgs_dumped; pgcnt_t i_cpr_storage_data_sz; /* in pages */ pgcnt_t i_cpr_storage_desc_pgcnt; /* in pages */ ushort_t cpr_mach_type = CPR_MACHTYPE_4U; static csu_md_t m_info; #define MAX_STORAGE_RETRY 3 #define MAX_STORAGE_ALLOC_RETRY 3 #define INITIAL_ALLOC_PCNT 40 /* starting allocation percentage */ #define INTEGRAL 100 /* to get 1% precision */ #define EXTRA_RATE 2 /* add EXTRA_RATE% extra space */ #define EXTRA_DESCS 10 #define CPR_NO_STORAGE_DESC 1 #define CPR_NO_STORAGE_DATA 2 #define CIF_SPLICE 0 #define CIF_UNLINK 1 /* * CPR miscellaneous support routines */ #define cpr_open(path, mode, vpp) (vn_open(path, UIO_SYSSPACE, \ mode, 0600, vpp, CRCREAT, 0)) #define cpr_rdwr(rw, vp, basep, cnt) (vn_rdwr(rw, vp, (caddr_t)(basep), \ cnt, 0LL, UIO_SYSSPACE, 0, (rlim64_t)MAXOFF_T, CRED(), \ (ssize_t *)NULL)) /* * definitions for saving/restoring prom pages */ static void *ppage_buf; static pgcnt_t ppage_count; static pfn_t *pphys_list; static size_t pphys_list_size; typedef void (*tlb_rw_t)(uint_t, tte_t *, uint64_t *); typedef void (*tlb_filter_t)(int, tte_t *, uint64_t, void *); /* * private struct for tlb handling */ struct cpr_trans_info { sutlb_t *dst; sutlb_t *tail; tlb_rw_t reader; tlb_rw_t writer; tlb_filter_t filter; int index; uint64_t skip; /* assumes TLB <= 64 locked entries */ }; typedef struct cpr_trans_info cti_t; /* * special handling for tlb info */ #define WITHIN_OFW(va) \ (((va) > (uint64_t)OFW_START_ADDR) && ((va) < (uint64_t)OFW_END_ADDR)) #define WITHIN_NUCLEUS(va, base) \ (((va) >= (base)) && \ (((va) + MMU_PAGESIZE) <= ((base) + MMU_PAGESIZE4M))) #define IS_BIGKTSB(va) \ (enable_bigktsb && \ ((va) >= (uint64_t)ktsb_base) && \ ((va) < (uint64_t)(ktsb_base + ktsb_sz))) /* * WARNING: * the text from this file is linked to follow cpr_resume_setup.o; * only add text between here and i_cpr_end_jumpback when it needs * to be called during resume before we switch back to the kernel * trap table. all the text in this range must fit within a page. */ /* * each time a machine is reset, the prom uses an inconsistent set of phys * pages and the cif cookie may differ as well. so prior to restoring the * original prom, we have to use to use the new/tmp prom's translations * when requesting prom services. * * cif_handler starts out as the original prom cookie, and that gets used * by client_handler() to jump into the prom. here we splice-in a wrapper * routine by writing cif_handler; client_handler() will now jump to the * wrapper which switches the %tba to the new/tmp prom's trap table then * jumps to the new cookie. */ void i_cpr_cif_setup(int action) { extern void *i_cpr_orig_cif, *cif_handler; extern int i_cpr_cif_wrapper(void *); /* * save the original cookie and change the current cookie to the * wrapper routine. later we just restore the original cookie. */ if (action == CIF_SPLICE) { i_cpr_orig_cif = cif_handler; cif_handler = (void *)i_cpr_cif_wrapper; } else if (action == CIF_UNLINK) cif_handler = i_cpr_orig_cif; } /* * launch slave cpus into kernel text, pause them, * and restore the original prom pages */ void i_cpr_mp_setup(void) { extern void restart_other_cpu(int); ihandle_t tmpout = 0; char *str; cpu_t *cp; uint64_t kctx = kcontextreg; /* * Do not allow setting page size codes in MMU primary context * register while using cif wrapper. This is needed to work * arround OBP incorrect handling of this MMU register. */ kcontextreg = 0; /* * reset cpu_ready_set so x_calls work properly */ CPUSET_ZERO(cpu_ready_set); CPUSET_ADD(cpu_ready_set, getprocessorid()); /* * setup cif to use the cookie from the new/tmp prom * and setup tmp handling for calling prom services. */ i_cpr_cif_setup(CIF_SPLICE); /* * at this point, only the nucleus and a few cpr pages are * mapped in. once we switch to the kernel trap table, * we can access the rest of kernel space. */ prom_set_traptable(&trap_table); if (ncpus > 1) { sfmmu_init_tsbs(); if (cpr_debug & LEVEL1) { prom_interpret("stdout @ swap l!", (uintptr_t)&tmpout, 0, 0, 0, 0); str = "MP startup...\r\n"; (void) prom_write(tmpout, str, strlen(str), 0, 0); } mutex_enter(&cpu_lock); /* * All of the slave cpus are not ready at this time, * yet the cpu structures have various cpu_flags set; * clear cpu_flags and mutex_ready. * Since we are coming up from a CPU suspend, the slave cpus * are frozen. */ for (cp = CPU->cpu_next; cp != CPU; cp = cp->cpu_next) { cp->cpu_flags = CPU_FROZEN; cp->cpu_m.mutex_ready = 0; } for (cp = CPU->cpu_next; cp != CPU; cp = cp->cpu_next) restart_other_cpu(cp->cpu_id); pause_cpus(NULL); mutex_exit(&cpu_lock); if (cpr_debug & LEVEL1) { str = "MP paused...\r\n"; (void) prom_write(tmpout, str, strlen(str), 0, 0); } i_cpr_xcall(i_cpr_clear_entries); } else i_cpr_clear_entries(0, 0); /* * now unlink the cif wrapper; WARNING: do not call any * prom_xxx() routines until after prom pages are restored. */ i_cpr_cif_setup(CIF_UNLINK); (void) i_cpr_prom_pages(CPR_PROM_RESTORE); /* allow setting page size codes in MMU primary context register */ kcontextreg = kctx; } /* * end marker for jumpback page; * this symbol is used to check the size of i_cpr_resume_setup() * and the above text. For simplicity, the Makefile needs to * link i_cpr_resume_setup.o and cpr_impl.o consecutively. */ void i_cpr_end_jumpback(void) { } /* * scan tlb entries with reader; when valid entries are found, * the filter routine will selectively save/clear them */ static void i_cpr_scan_tlb(cti_t *ctip) { uint64_t va_tag; int tlb_index; tte_t tte; for (tlb_index = ctip->index; tlb_index >= 0; tlb_index--) { (*ctip->reader)((uint_t)tlb_index, &tte, &va_tag); if (va_tag && TTE_IS_VALID(&tte)) (*ctip->filter)(tlb_index, &tte, va_tag, ctip); } } /* * filter for locked tlb entries that reference the text/data nucleus * and any bigktsb's; these will be reinstalled by cprboot on all cpus */ /* ARGSUSED */ static void i_cpr_lnb(int index, tte_t *ttep, uint64_t va_tag, void *ctrans) { cti_t *ctip; /* * record tlb data at ctip->dst; the target tlb index starts * at the highest tlb offset and moves towards 0. the prom * reserves both dtlb and itlb index 0. any selected entry * also gets marked to prevent being flushed during resume */ if (TTE_IS_LOCKED(ttep) && (va_tag == (uint64_t)textva || va_tag == (uint64_t)datava || IS_BIGKTSB(va_tag))) { ctip = ctrans; while ((1 << ctip->index) & ctip->skip) ctip->index--; ASSERT(ctip->index > 0); ASSERT(ctip->dst < ctip->tail); ctip->dst->tte.ll = ttep->ll; ctip->dst->va_tag = va_tag; ctip->dst->index = ctip->index--; ctip->dst->tmp = 0; ctip->dst++; } } /* * some tlb entries are stale, filter for unlocked entries * within the prom virt range and clear them */ static void i_cpr_ufw(int index, tte_t *ttep, uint64_t va_tag, void *ctrans) { sutlb_t clr; cti_t *ctip; if (!TTE_IS_LOCKED(ttep) && WITHIN_OFW(va_tag)) { ctip = ctrans; bzero(&clr, sizeof (clr)); (*ctip->writer)((uint_t)index, &clr.tte, &clr.va_tag); } } /* * some of the entries installed by cprboot are needed only on a * short-term basis and need to be flushed to avoid clogging the tlbs. * scan the dtte/itte arrays for items marked as temporary and clear * dtlb/itlb entries using wrfunc. */ static void i_cpr_clear_tmp(sutlb_t *listp, int max, tlb_rw_t wrfunc) { sutlb_t clr, *tail; bzero(&clr, sizeof (clr)); for (tail = listp + max; listp < tail && listp->va_tag; listp++) { if (listp->tmp) (*wrfunc)((uint_t)listp->index, &clr.tte, &clr.va_tag); } } /* ARGSUSED */ static void i_cpr_clear_entries(uint64_t arg1, uint64_t arg2) { extern void demap_all(void); cti_t cti; i_cpr_clear_tmp(m_info.dtte, CPR_MAX_TLB, dtlb_wr_entry); i_cpr_clear_tmp(m_info.itte, CPR_MAX_TLB, itlb_wr_entry); /* * for newer cpus that implement DEMAP_ALL_TYPE, demap_all is * a second label for vtag_flushall. the call is made using * vtag_flushall() instead of demap_all() due to runtime and * krtld results with both older and newer cpu modules. */ if (&demap_all != 0) { vtag_flushall(); return; } /* * for older V9 cpus, scan tlbs and clear stale entries */ bzero(&cti, sizeof (cti)); cti.filter = i_cpr_ufw; cti.index = cpunodes[CPU->cpu_id].dtlb_size - 1; cti.reader = dtlb_rd_entry; cti.writer = dtlb_wr_entry; i_cpr_scan_tlb(&cti); cti.index = cpunodes[CPU->cpu_id].itlb_size - 1; cti.reader = itlb_rd_entry; cti.writer = itlb_wr_entry; i_cpr_scan_tlb(&cti); } /* * craft tlb info for tmp use during resume; this data gets used by * cprboot to install tlb entries. we also mark each struct as tmp * so those tlb entries will get flushed after switching to the kernel * trap table. no data needs to be recorded for vaddr when it falls * within the nucleus since we've already recorded nucleus ttes and * a 8K tte would conflict with a 4MB tte. eg: the cpr module * text/data may have been loaded into the text/data nucleus. */ static void i_cpr_make_tte(cti_t *ctip, void *vaddr, caddr_t nbase) { pfn_t ppn; uint_t rw; if (WITHIN_NUCLEUS((caddr_t)vaddr, nbase)) return; while ((1 << ctip->index) & ctip->skip) ctip->index--; ASSERT(ctip->index > 0); ASSERT(ctip->dst < ctip->tail); /* * without any global service available to lookup * a tte by vaddr, we craft our own here: */ ppn = va_to_pfn(vaddr); rw = (nbase == datava) ? TTE_HWWR_INT : 0; ctip->dst->tte.tte_inthi = TTE_VALID_INT | TTE_PFN_INTHI(ppn); ctip->dst->tte.tte_intlo = TTE_PFN_INTLO(ppn) | TTE_LCK_INT | TTE_CP_INT | TTE_PRIV_INT | rw; ctip->dst->va_tag = ((uintptr_t)vaddr & MMU_PAGEMASK); ctip->dst->index = ctip->index--; ctip->dst->tmp = 1; ctip->dst++; } static void i_cpr_xcall(xcfunc_t func) { uint_t pil, reset_pil; pil = getpil(); if (pil < XCALL_PIL) reset_pil = 0; else { reset_pil = 1; setpil(XCALL_PIL - 1); } xc_some(cpu_ready_set, func, 0, 0); if (reset_pil) setpil(pil); } /* * restart paused slave cpus */ void i_cpr_machdep_setup(void) { if (ncpus > 1) { DEBUG1(errp("MP restarted...\n")); mutex_enter(&cpu_lock); start_cpus(); mutex_exit(&cpu_lock); } } /* * Stop all interrupt activities in the system */ void i_cpr_stop_intr(void) { (void) spl7(); } /* * Set machine up to take interrupts */ void i_cpr_enable_intr(void) { (void) spl0(); } /* * record cpu nodes and ids */ static void i_cpr_save_cpu_info(void) { struct sun4u_cpu_info *scip; cpu_t *cp; scip = m_info.sci; cp = CPU; do { ASSERT(scip < &m_info.sci[NCPU]); scip->cpu_id = cp->cpu_id; scip->node = cpunodes[cp->cpu_id].nodeid; scip++; } while ((cp = cp->cpu_next) != CPU); } /* * Write necessary machine dependent information to cpr state file, * eg. sun4u mmu ctx secondary for the current running process (cpr) ... */ int i_cpr_write_machdep(vnode_t *vp) { extern uint_t getpstate(), getwstate(); extern uint_t i_cpr_tstack_size; const char ustr[] = ": unix-tte 2drop false ;"; uintptr_t tinfo; label_t *ltp; cmd_t cmach; char *fmt; int rc; /* * ustr[] is used as temporary forth words during * slave startup sequence, see sfmmu_mp_startup() */ cmach.md_magic = (uint_t)CPR_MACHDEP_MAGIC; cmach.md_size = sizeof (m_info) + sizeof (ustr); if (rc = cpr_write(vp, (caddr_t)&cmach, sizeof (cmach))) { cpr_err(CE_WARN, "Failed to write descriptor."); return (rc); } /* * m_info is now cleared in i_cpr_dump_setup() */ m_info.ksb = (uint32_t)STACK_BIAS; m_info.kpstate = (uint16_t)getpstate(); m_info.kwstate = (uint16_t)getwstate(); DEBUG1(errp("stack bias 0x%x, pstate 0x%x, wstate 0x%x\n", m_info.ksb, m_info.kpstate, m_info.kwstate)); ltp = &ttolwp(curthread)->lwp_qsav; m_info.qsav_pc = (cpr_ext)ltp->val[0]; m_info.qsav_sp = (cpr_ext)ltp->val[1]; /* * Set secondary context to INVALID_CONTEXT to force the HAT * to re-setup the MMU registers and locked TTEs it needs for * TLB miss handling. */ m_info.mmu_ctx_sec = INVALID_CONTEXT; m_info.mmu_ctx_pri = KCONTEXT; tinfo = (uintptr_t)curthread; m_info.thrp = (cpr_ptr)tinfo; tinfo = (uintptr_t)i_cpr_resume_setup; m_info.func = (cpr_ptr)tinfo; /* * i_cpr_data_page is comprised of a 4K stack area and a few * trailing data symbols; the page is shared by the prom and * kernel during resume. the stack size is recorded here * and used by cprboot to set %sp */ tinfo = (uintptr_t)&i_cpr_data_page; m_info.tmp_stack = (cpr_ptr)tinfo; m_info.tmp_stacksize = i_cpr_tstack_size; m_info.test_mode = cpr_test_mode; i_cpr_save_cpu_info(); if (rc = cpr_write(vp, (caddr_t)&m_info, sizeof (m_info))) { cpr_err(CE_WARN, "Failed to write machdep info."); return (rc); } fmt = "error writing %s forth info"; if (rc = cpr_write(vp, (caddr_t)ustr, sizeof (ustr))) cpr_err(CE_WARN, fmt, "unix-tte"); return (rc); } /* * Save miscellaneous information which needs to be written to the * state file. This information is required to re-initialize * kernel/prom handshaking. */ void i_cpr_save_machdep_info(void) { DEBUG5(errp("jumpback size = 0x%lx\n", (uintptr_t)&i_cpr_end_jumpback - (uintptr_t)i_cpr_resume_setup)); /* * Verify the jumpback code all falls in one page. */ if (((uintptr_t)&i_cpr_end_jumpback & MMU_PAGEMASK) != ((uintptr_t)i_cpr_resume_setup & MMU_PAGEMASK)) cpr_err(CE_PANIC, "jumpback code exceeds one page."); } void i_cpr_set_tbr(void) { } /* * cpu0 should contain bootcpu info */ cpu_t * i_cpr_bootcpu(void) { return (&cpu0); } /* * Return the virtual address of the mapping area */ caddr_t i_cpr_map_setup(void) { /* * Allocate a virtual memory range spanned by an hmeblk. * This would be 8 hments or 64k bytes. Starting VA * must be 64k (8-page) aligned. */ cpr_vaddr = vmem_xalloc(heap_arena, mmu_ptob(NHMENTS), mmu_ptob(NHMENTS), 0, 0, NULL, NULL, VM_NOSLEEP); return (cpr_vaddr); } /* * create tmp locked tlb entries for a group of phys pages; * * i_cpr_mapin/i_cpr_mapout should always be called in pairs, * otherwise would fill up a tlb with locked entries */ void i_cpr_mapin(caddr_t vaddr, uint_t pages, pfn_t ppn) { tte_t tte; extern pfn_t curthreadpfn; extern int curthreadremapped; curthreadremapped = (ppn <= curthreadpfn && curthreadpfn < ppn + pages); for (; pages--; ppn++, vaddr += MMU_PAGESIZE) { tte.tte_inthi = TTE_VALID_INT | TTE_PFN_INTHI(ppn); tte.tte_intlo = TTE_PFN_INTLO(ppn) | TTE_LCK_INT | TTE_CP_INT | TTE_PRIV_INT | TTE_HWWR_INT; sfmmu_dtlb_ld(vaddr, KCONTEXT, &tte); } } void i_cpr_mapout(caddr_t vaddr, uint_t pages) { extern int curthreadremapped; if (curthreadremapped && vaddr <= (caddr_t)curthread && (caddr_t)curthread < vaddr + pages * MMU_PAGESIZE) curthreadremapped = 0; for (; pages--; vaddr += MMU_PAGESIZE) vtag_flushpage(vaddr, KCONTEXT); } /* * We're done using the mapping area; release virtual space */ void i_cpr_map_destroy(void) { vmem_free(heap_arena, cpr_vaddr, mmu_ptob(NHMENTS)); cpr_vaddr = NULL; } /* ARGSUSED */ void i_cpr_handle_xc(int flag) { } /* * This function takes care of pages which are not in kas or need to be * taken care of in a special way. For example, panicbuf pages are not * in kas and their pages are allocated via prom_retain(). */ pgcnt_t i_cpr_count_special_kpages(int mapflag, bitfunc_t bitfunc) { struct cpr_map_info *pri, *tail; pgcnt_t pages, total = 0; pfn_t pfn; /* * Save information about prom retained panicbuf pages */ if (bitfunc == cpr_setbit) { pri = &cpr_prom_retain[CPR_PANICBUF]; pri->virt = (cpr_ptr)panicbuf; pri->phys = va_to_pa(panicbuf); pri->size = sizeof (panicbuf); } /* * Go through the prom_retain array to tag those pages. */ tail = &cpr_prom_retain[CPR_PROM_RETAIN_CNT]; for (pri = cpr_prom_retain; pri < tail; pri++) { pages = mmu_btopr(pri->size); for (pfn = ADDR_TO_PN(pri->phys); pages--; pfn++) { if (pf_is_memory(pfn)) { if (bitfunc == cpr_setbit) { if ((*bitfunc)(pfn, mapflag) == 0) total++; } else total++; } } } return (total); } /* * Free up memory-related resources here. We start by freeing buffers * allocated during suspend initialization. Also, free up the mapping * resources allocated in cpr_init(). */ void i_cpr_free_memory_resources(void) { (void) i_cpr_prom_pages(CPR_PROM_FREE); i_cpr_map_destroy(); i_cpr_storage_free(); } /* * Derived from cpr_write_statefile(). * Save the sensitive pages to the storage area and do bookkeeping * using the sensitive descriptors. Each descriptor will contain no more * than CPR_MAXCONTIG amount of contiguous pages to match the max amount * of pages that statefile gets written to disk at each write. * XXX The CPR_MAXCONTIG can be changed to the size of the compression * scratch area. */ static int i_cpr_save_to_storage(void) { sensitive_size_saved = 0; sensitive_pages_saved = 0; sensitive_write_ptr = i_cpr_storage_data_base; return (cpr_contig_pages(NULL, SAVE_TO_STORAGE)); } /* * This routine allocates space to save the sensitive kernel pages, * i.e. kernel data nucleus, kvalloc and kvseg segments. * It's assumed that those segments are the only areas that can be * contaminated by memory allocations during statefile dumping. * The space allocated here contains: * A list of descriptors describing the saved sensitive pages. * The storage area for saving the compressed sensitive kernel pages. * Since storage pages are allocated from segkmem, they need to be * excluded when saving. */ int i_cpr_save_sensitive_kpages(void) { static const char pages_fmt[] = "\n%s %s allocs\n" " spages %ld, vpages %ld, diff %ld\n"; int retry_cnt; int error = 0; pgcnt_t pages, spages, vpages; caddr_t addr; char *str; /* * Tag sensitive kpages. Allocate space for storage descriptors * and storage data area based on the resulting bitmaps. * Note: The storage space will be part of the sensitive * segment, so we need to tag kpages here before the storage * is actually allocated just so their space won't be accounted * for. They will not be part of the statefile although those * pages will be claimed by cprboot. */ cpr_clear_bitmaps(); spages = i_cpr_count_sensitive_kpages(REGULAR_BITMAP, cpr_setbit); vpages = cpr_count_volatile_pages(REGULAR_BITMAP, cpr_clrbit); pages = spages - vpages; str = "i_cpr_save_sensitive_kpages:"; DEBUG7(errp(pages_fmt, "before", str, spages, vpages, pages)); /* * Allocate space to save the clean sensitive kpages */ for (retry_cnt = 0; retry_cnt < MAX_STORAGE_ALLOC_RETRY; retry_cnt++) { /* * Alloc on first pass or realloc if we are retrying because * of insufficient storage for sensitive pages */ if (retry_cnt == 0 || error == ENOMEM) { if (i_cpr_storage_data_base) { kmem_free(i_cpr_storage_data_base, mmu_ptob(i_cpr_storage_data_sz)); i_cpr_storage_data_base = NULL; i_cpr_storage_data_sz = 0; } addr = i_cpr_storage_data_alloc(pages, &i_cpr_storage_data_sz, retry_cnt); if (addr == NULL) { DEBUG7(errp( "\n%s can't allocate data storage space!\n", str)); return (ENOMEM); } i_cpr_storage_data_base = addr; i_cpr_storage_data_end = addr + mmu_ptob(i_cpr_storage_data_sz); } /* * Allocate on first pass, only realloc if retry is because of * insufficient descriptors, but reset contents on each pass * (desc_alloc resets contents as well) */ if (retry_cnt == 0 || error == -1) { error = i_cpr_storage_desc_alloc( &i_cpr_storage_desc_base, &i_cpr_storage_desc_pgcnt, &i_cpr_storage_desc_end, retry_cnt); if (error != 0) return (error); } else { i_cpr_storage_desc_init(i_cpr_storage_desc_base, i_cpr_storage_desc_pgcnt, i_cpr_storage_desc_end); } /* * We are ready to save the sensitive kpages to storage. * We cannot trust what's tagged in the bitmaps anymore * after storage allocations. Clear up the bitmaps and * retag the sensitive kpages again. The storage pages * should be untagged. */ cpr_clear_bitmaps(); spages = i_cpr_count_sensitive_kpages(REGULAR_BITMAP, cpr_setbit); vpages = cpr_count_volatile_pages(REGULAR_BITMAP, cpr_clrbit); DEBUG7(errp(pages_fmt, "after ", str, spages, vpages, spages - vpages)); /* * Returns 0 on success, -1 if too few descriptors, and * ENOMEM if not enough space to save sensitive pages */ DEBUG1(errp("compressing pages to storage...\n")); error = i_cpr_save_to_storage(); if (error == 0) { /* Saving to storage succeeded */ DEBUG1(errp("compressed %d pages\n", sensitive_pages_saved)); break; } else if (error == -1) DEBUG1(errp("%s too few descriptors\n", str)); } if (error == -1) error = ENOMEM; return (error); } /* * Estimate how much memory we will need to save * the sensitive pages with compression. */ static caddr_t i_cpr_storage_data_alloc(pgcnt_t pages, pgcnt_t *alloc_pages, int retry_cnt) { pgcnt_t alloc_pcnt, last_pcnt; caddr_t addr; char *str; str = "i_cpr_storage_data_alloc:"; if (retry_cnt == 0) { /* * common compression ratio is about 3:1 * initial storage allocation is estimated at 40% * to cover the majority of cases */ alloc_pcnt = INITIAL_ALLOC_PCNT; *alloc_pages = (pages * alloc_pcnt) / INTEGRAL; DEBUG7(errp("%s sensitive pages: %ld\n", str, pages)); DEBUG7(errp("%s initial est pages: %ld, alloc %ld%%\n", str, *alloc_pages, alloc_pcnt)); } else { /* * calculate the prior compression percentage (x100) * from the last attempt to save sensitive pages */ ASSERT(sensitive_pages_saved != 0); last_pcnt = (mmu_btopr(sensitive_size_saved) * INTEGRAL) / sensitive_pages_saved; DEBUG7(errp("%s last ratio %ld%%\n", str, last_pcnt)); /* * new estimated storage size is based on * the larger ratio + 5% for each retry: * pages * (last + [5%, 10%]) */ alloc_pcnt = MAX(last_pcnt, INITIAL_ALLOC_PCNT) + (retry_cnt * 5); *alloc_pages = (pages * alloc_pcnt) / INTEGRAL; DEBUG7(errp("%s Retry est pages: %ld, alloc %ld%%\n", str, *alloc_pages, alloc_pcnt)); } addr = kmem_alloc(mmu_ptob(*alloc_pages), KM_NOSLEEP); DEBUG7(errp("%s alloc %ld pages\n", str, *alloc_pages)); return (addr); } void i_cpr_storage_free(void) { /* Free descriptors */ if (i_cpr_storage_desc_base) { kmem_free(i_cpr_storage_desc_base, mmu_ptob(i_cpr_storage_desc_pgcnt)); i_cpr_storage_desc_base = NULL; i_cpr_storage_desc_pgcnt = 0; } /* Data storage */ if (i_cpr_storage_data_base) { kmem_free(i_cpr_storage_data_base, mmu_ptob(i_cpr_storage_data_sz)); i_cpr_storage_data_base = NULL; i_cpr_storage_data_sz = 0; } } /* * This routine is derived from cpr_compress_and_write(). * 1. Do bookkeeping in the descriptor for the contiguous sensitive chunk. * 2. Compress and save the clean sensitive pages into the storage area. */ int i_cpr_compress_and_save(int chunks, pfn_t spfn, pgcnt_t pages) { extern char *cpr_compress_pages(cpd_t *, pgcnt_t, int); extern caddr_t i_cpr_storage_data_end; uint_t remaining, datalen; uint32_t test_usum; char *datap; csd_t *descp; cpd_t cpd; int error; /* * Fill next empty storage descriptor */ descp = i_cpr_storage_desc_base + chunks - 1; if (descp >= i_cpr_storage_desc_end) { DEBUG1(errp("ran out of descriptors, base 0x%p, chunks %d, " "end 0x%p, descp 0x%p\n", i_cpr_storage_desc_base, chunks, i_cpr_storage_desc_end, descp)); return (-1); } ASSERT(descp->csd_dirty_spfn == (uint_t)-1); i_cpr_storage_desc_last_used = descp; descp->csd_dirty_spfn = spfn; descp->csd_dirty_npages = pages; i_cpr_mapin(CPR->c_mapping_area, pages, spfn); /* * try compressing pages and copy cpd fields * pfn is copied for debug use */ cpd.cpd_pfn = spfn; datap = cpr_compress_pages(&cpd, pages, C_COMPRESSING); datalen = cpd.cpd_length; descp->csd_clean_compressed = (cpd.cpd_flag & CPD_COMPRESS); #ifdef DEBUG descp->csd_usum = cpd.cpd_usum; descp->csd_csum = cpd.cpd_csum; #endif error = 0; /* * Save the raw or compressed data to the storage area pointed to by * sensitive_write_ptr. Make sure the storage space is big enough to * hold the result. Otherwise roll back to increase the storage space. */ descp->csd_clean_sva = (cpr_ptr)sensitive_write_ptr; descp->csd_clean_sz = datalen; if ((sensitive_write_ptr + datalen) < i_cpr_storage_data_end) { extern void cprbcopy(void *, void *, size_t); cprbcopy(datap, sensitive_write_ptr, datalen); sensitive_size_saved += datalen; sensitive_pages_saved += descp->csd_dirty_npages; sensitive_write_ptr += datalen; } else { remaining = (i_cpr_storage_data_end - sensitive_write_ptr); DEBUG1(errp("i_cpr_compress_and_save: The storage " "space is too small!\ngot %d, want %d\n\n", remaining, (remaining + datalen))); #ifdef DEBUG /* * Check to see if the content of the sensitive pages that we * just copied have changed during this small time window. */ test_usum = checksum32(CPR->c_mapping_area, mmu_ptob(pages)); descp->csd_usum = cpd.cpd_usum; if (test_usum != descp->csd_usum) { DEBUG1(errp("\nWARNING: i_cpr_compress_and_save: " "Data in the range of pfn 0x%x to pfn " "0x%x has changed after they are saved " "into storage.", spfn, (spfn + pages - 1))); } #endif error = ENOMEM; } i_cpr_mapout(CPR->c_mapping_area, pages); return (error); } /* * This routine is derived from cpr_count_kpages(). * It goes through kernel data nucleus and segkmem segments to select * pages in use and mark them in the corresponding bitmap. */ pgcnt_t i_cpr_count_sensitive_kpages(int mapflag, bitfunc_t bitfunc) { pgcnt_t kdata_cnt = 0, segkmem_cnt = 0; extern caddr_t e_moddata; extern struct seg kvalloc; extern struct seg kmem64; size_t size; /* * Kernel data nucleus pages */ size = e_moddata - s_data; kdata_cnt += cpr_count_pages(s_data, size, mapflag, bitfunc, DBG_SHOWRANGE); /* * kvseg and kvalloc pages */ segkmem_cnt += cpr_scan_kvseg(mapflag, bitfunc, &kvseg); segkmem_cnt += cpr_count_pages(kvalloc.s_base, kvalloc.s_size, mapflag, bitfunc, DBG_SHOWRANGE); /* segment to support kernel memory usage above 32-bit space (4GB) */ if (kmem64.s_base) segkmem_cnt += cpr_count_pages(kmem64.s_base, kmem64.s_size, mapflag, bitfunc, DBG_SHOWRANGE); DEBUG7(errp("\ni_cpr_count_sensitive_kpages:\n" "\tkdata_cnt %ld + segkmem_cnt %ld = %ld pages\n", kdata_cnt, segkmem_cnt, kdata_cnt + segkmem_cnt)); return (kdata_cnt + segkmem_cnt); } pgcnt_t i_cpr_count_storage_pages(int mapflag, bitfunc_t bitfunc) { pgcnt_t count = 0; if (i_cpr_storage_desc_base) { count += cpr_count_pages((caddr_t)i_cpr_storage_desc_base, (size_t)mmu_ptob(i_cpr_storage_desc_pgcnt), mapflag, bitfunc, DBG_SHOWRANGE); } if (i_cpr_storage_data_base) { count += cpr_count_pages(i_cpr_storage_data_base, (size_t)mmu_ptob(i_cpr_storage_data_sz), mapflag, bitfunc, DBG_SHOWRANGE); } return (count); } /* * Derived from cpr_write_statefile(). * Allocate (or reallocate after exhausting the supply) descriptors for each * chunk of contiguous sensitive kpages. */ static int i_cpr_storage_desc_alloc(csd_t **basepp, pgcnt_t *pgsp, csd_t **endpp, int retry) { pgcnt_t npages; int chunks; csd_t *descp, *end; size_t len; char *str = "i_cpr_storage_desc_alloc:"; /* * On initial allocation, add some extra to cover overhead caused * by the allocation for the storage area later. */ if (retry == 0) { chunks = cpr_contig_pages(NULL, STORAGE_DESC_ALLOC) + EXTRA_DESCS; npages = mmu_btopr(sizeof (**basepp) * (pgcnt_t)chunks); DEBUG7(errp("%s chunks %d, ", str, chunks)); } else { DEBUG7(errp("%s retry %d: ", str, retry)); npages = *pgsp + 1; } /* Free old descriptors, if any */ if (*basepp) kmem_free((caddr_t)*basepp, mmu_ptob(*pgsp)); descp = *basepp = kmem_alloc(mmu_ptob(npages), KM_NOSLEEP); if (descp == NULL) { DEBUG7(errp("%s no space for descriptors!\n", str)); return (ENOMEM); } *pgsp = npages; len = mmu_ptob(npages); end = *endpp = descp + (len / (sizeof (**basepp))); DEBUG7(errp("npages 0x%x, len 0x%x, items 0x%x\n\t*basepp " "%p, *endpp %p\n", npages, len, (len / (sizeof (**basepp))), *basepp, *endpp)); i_cpr_storage_desc_init(descp, npages, end); return (0); } static void i_cpr_storage_desc_init(csd_t *descp, pgcnt_t npages, csd_t *end) { size_t len = mmu_ptob(npages); /* Initialize the descriptors to something impossible. */ bzero(descp, len); #ifdef DEBUG /* * This condition is tested by an ASSERT */ for (; descp < end; descp++) descp->csd_dirty_spfn = (uint_t)-1; #endif } int i_cpr_dump_sensitive_kpages(vnode_t *vp) { int error = 0; uint_t spin_cnt = 0; csd_t *descp; /* * These following two variables need to be reinitialized * for each cpr cycle. */ i_cpr_sensitive_bytes_dumped = 0; i_cpr_sensitive_pgs_dumped = 0; if (i_cpr_storage_desc_base) { for (descp = i_cpr_storage_desc_base; descp <= i_cpr_storage_desc_last_used; descp++) { if (error = cpr_dump_sensitive(vp, descp)) return (error); spin_cnt++; if ((spin_cnt & 0x5F) == 1) cpr_spinning_bar(); } prom_printf(" \b"); } DEBUG7(errp("\ni_cpr_dump_sensitive_kpages: dumped %d\n", i_cpr_sensitive_pgs_dumped)); return (0); } /* * 1. Fill the cpr page descriptor with the info of the dirty pages * and * write the descriptor out. It will be used at resume. * 2. Write the clean data in stead of the dirty data out. * Note: to save space, the clean data is already compressed. */ static int cpr_dump_sensitive(vnode_t *vp, csd_t *descp) { int error = 0; caddr_t datap; cpd_t cpd; /* cpr page descriptor */ pfn_t dirty_spfn; pgcnt_t dirty_npages; size_t clean_sz; caddr_t clean_sva; int clean_compressed; extern uchar_t cpr_pagecopy[]; dirty_spfn = descp->csd_dirty_spfn; dirty_npages = descp->csd_dirty_npages; clean_sva = (caddr_t)descp->csd_clean_sva; clean_sz = descp->csd_clean_sz; clean_compressed = descp->csd_clean_compressed; /* Fill cpr page descriptor. */ cpd.cpd_magic = (uint_t)CPR_PAGE_MAGIC; cpd.cpd_pfn = dirty_spfn; cpd.cpd_flag = 0; /* must init to zero */ cpd.cpd_pages = dirty_npages; #ifdef DEBUG if ((cpd.cpd_usum = descp->csd_usum) != 0) cpd.cpd_flag |= CPD_USUM; if ((cpd.cpd_csum = descp->csd_csum) != 0) cpd.cpd_flag |= CPD_CSUM; #endif STAT->cs_dumped_statefsz += mmu_ptob(dirty_npages); /* * The sensitive kpages are usually saved with compression * unless compression could not reduce the size of the data. * If user choose not to have the statefile compressed, * we need to decompress the data back before dumping it to disk. */ if (CPR->c_flags & C_COMPRESSING) { cpd.cpd_length = clean_sz; datap = clean_sva; if (clean_compressed) cpd.cpd_flag |= CPD_COMPRESS; } else { if (clean_compressed) { cpd.cpd_length = decompress(clean_sva, cpr_pagecopy, clean_sz, mmu_ptob(dirty_npages)); datap = (caddr_t)cpr_pagecopy; ASSERT(cpd.cpd_length == mmu_ptob(dirty_npages)); } else { cpd.cpd_length = clean_sz; datap = clean_sva; } cpd.cpd_csum = 0; } /* Write cpr page descriptor */ error = cpr_write(vp, (caddr_t)&cpd, sizeof (cpd)); if (error) { DEBUG7(errp("descp: %x\n", descp)); #ifdef DEBUG debug_enter("cpr_dump_sensitive: cpr_write() page " "descriptor failed!\n"); #endif return (error); } i_cpr_sensitive_bytes_dumped += sizeof (cpd_t); /* Write page data */ error = cpr_write(vp, (caddr_t)datap, cpd.cpd_length); if (error) { DEBUG7(errp("error: %x\n", error)); DEBUG7(errp("descp: %x\n", descp)); DEBUG7(errp("cpr_write(%x, %x , %x)\n", vp, datap, cpd.cpd_length)); #ifdef DEBUG debug_enter("cpr_dump_sensitive: cpr_write() data failed!\n"); #endif return (error); } i_cpr_sensitive_bytes_dumped += cpd.cpd_length; i_cpr_sensitive_pgs_dumped += dirty_npages; return (error); } /* * Sanity check to make sure that we have dumped right amount * of pages from different sources to statefile. */ int i_cpr_check_pgs_dumped(uint_t pgs_expected, uint_t regular_pgs_dumped) { uint_t total_pgs_dumped; total_pgs_dumped = regular_pgs_dumped + i_cpr_sensitive_pgs_dumped; DEBUG7(errp("\ncheck_pgs: reg %d + sens %d = %d, expect %d\n\n", regular_pgs_dumped, i_cpr_sensitive_pgs_dumped, total_pgs_dumped, pgs_expected)); if (pgs_expected == total_pgs_dumped) return (0); return (EINVAL); } int i_cpr_reusefini(void) { struct vnode *vp; cdef_t *cdef; size_t size; char *bufp; int rc; if (cpr_reusable_mode) cpr_reusable_mode = 0; if (rc = cpr_open_deffile(FREAD|FWRITE, &vp)) { if (rc == EROFS) { cpr_err(CE_CONT, "uadmin A_FREEZE AD_REUSEFINI " "(uadmin %d %d)\nmust be done with / mounted " "writeable.\n", A_FREEZE, AD_REUSEFINI); } return (rc); } cdef = kmem_alloc(sizeof (*cdef), KM_SLEEP); rc = cpr_rdwr(UIO_READ, vp, cdef, sizeof (*cdef)); if (rc) { cpr_err(CE_WARN, "Failed reading %s, errno = %d", cpr_default_path, rc); } else if (cdef->mini.magic != CPR_DEFAULT_MAGIC) { cpr_err(CE_WARN, "bad magic number in %s, cannot restore " "prom values for %s", cpr_default_path, cpr_enumerate_promprops(&bufp, &size)); kmem_free(bufp, size); rc = EINVAL; } else { /* * clean up prom properties */ rc = cpr_update_nvram(cdef->props); if (rc == 0) { /* * invalidate the disk copy and turn off reusable */ cdef->mini.magic = 0; cdef->mini.reusable = 0; if (rc = cpr_rdwr(UIO_WRITE, vp, &cdef->mini, sizeof (cdef->mini))) { cpr_err(CE_WARN, "Failed writing %s, errno %d", cpr_default_path, rc); } } } (void) VOP_CLOSE(vp, FREAD|FWRITE, 1, (offset_t)0, CRED()); VN_RELE(vp); kmem_free(cdef, sizeof (*cdef)); return (rc); } int i_cpr_reuseinit(void) { int rc = 0; if (rc = cpr_default_setup(1)) return (rc); /* * We need to validate default file */ rc = cpr_validate_definfo(1); if (rc == 0) cpr_reusable_mode = 1; else if (rc == EROFS) { cpr_err(CE_NOTE, "reuseinit must be performed " "while / is mounted writeable"); } (void) cpr_default_setup(0); return (rc); } int i_cpr_check_cprinfo(void) { struct vnode *vp; cmini_t mini; int rc = 0; if (rc = cpr_open_deffile(FREAD, &vp)) { if (rc == ENOENT) cpr_err(CE_NOTE, "cprinfo file does not " "exist. You must run 'uadmin %d %d' " "command while / is mounted writeable,\n" "then reboot and run 'uadmin %d %d' " "to create a reusable statefile", A_FREEZE, AD_REUSEINIT, A_FREEZE, AD_REUSABLE); return (rc); } rc = cpr_rdwr(UIO_READ, vp, &mini, sizeof (mini)); (void) VOP_CLOSE(vp, FREAD, 1, (offset_t)0, CRED()); VN_RELE(vp); if (rc) { cpr_err(CE_WARN, "Failed reading %s, errno = %d", cpr_default_path, rc); } else if (mini.magic != CPR_DEFAULT_MAGIC) { cpr_err(CE_CONT, "bad magic number in cprinfo file.\n" "You must run 'uadmin %d %d' while / is mounted " "writeable, then reboot and run 'uadmin %d %d' " "to create a reusable statefile\n", A_FREEZE, AD_REUSEINIT, A_FREEZE, AD_REUSABLE); rc = EINVAL; } return (rc); } int i_cpr_reusable_supported(void) { return (1); } /* * find prom phys pages and alloc space for a tmp copy */ static int i_cpr_find_ppages(void) { extern struct vnode prom_ppages; struct page *pp; struct memlist *pmem; pgcnt_t npages, pcnt, scnt, vcnt; pfn_t ppn, plast, *dst; int mapflag; cpr_clear_bitmaps(); mapflag = REGULAR_BITMAP; /* * there should be a page_t for each phys page used by the kernel; * set a bit for each phys page not tracked by a page_t */ pcnt = 0; memlist_read_lock(); for (pmem = phys_install; pmem; pmem = pmem->next) { npages = mmu_btop(pmem->size); ppn = mmu_btop(pmem->address); for (plast = ppn + npages; ppn < plast; ppn++) { if (page_numtopp_nolock(ppn)) continue; (void) cpr_setbit(ppn, mapflag); pcnt++; } } memlist_read_unlock(); /* * clear bits for phys pages in each segment */ scnt = cpr_count_seg_pages(mapflag, cpr_clrbit); /* * set bits for phys pages referenced by the prom_ppages vnode; * these pages are mostly comprised of forthdebug words */ vcnt = 0; for (pp = prom_ppages.v_pages; pp; ) { if (cpr_setbit(pp->p_offset, mapflag) == 0) vcnt++; pp = pp->p_vpnext; if (pp == prom_ppages.v_pages) break; } /* * total number of prom pages are: * (non-page_t pages - seg pages + vnode pages) */ ppage_count = pcnt - scnt + vcnt; DEBUG1(errp("find_ppages: pcnt %ld - scnt %ld + vcnt %ld = %ld\n", pcnt, scnt, vcnt, ppage_count)); /* * alloc array of pfn_t to store phys page list */ pphys_list_size = ppage_count * sizeof (pfn_t); pphys_list = kmem_alloc(pphys_list_size, KM_NOSLEEP); if (pphys_list == NULL) { cpr_err(CE_WARN, "cannot alloc pphys_list"); return (ENOMEM); } /* * phys pages referenced in the bitmap should be * those used by the prom; scan bitmap and save * a list of prom phys page numbers */ dst = pphys_list; memlist_read_lock(); for (pmem = phys_install; pmem; pmem = pmem->next) { npages = mmu_btop(pmem->size); ppn = mmu_btop(pmem->address); for (plast = ppn + npages; ppn < plast; ppn++) { if (cpr_isset(ppn, mapflag)) { ASSERT(dst < (pphys_list + ppage_count)); *dst++ = ppn; } } } memlist_read_unlock(); /* * allocate space to store prom pages */ ppage_buf = kmem_alloc(mmu_ptob(ppage_count), KM_NOSLEEP); if (ppage_buf == NULL) { kmem_free(pphys_list, pphys_list_size); pphys_list = NULL; cpr_err(CE_WARN, "cannot alloc ppage_buf"); return (ENOMEM); } return (0); } /* * save prom pages to kmem pages */ static void i_cpr_save_ppages(void) { pfn_t *pphys, *plast; caddr_t dst; /* * map in each prom page and copy to a kmem page */ dst = ppage_buf; plast = pphys_list + ppage_count; for (pphys = pphys_list; pphys < plast; pphys++) { i_cpr_mapin(cpr_vaddr, 1, *pphys); bcopy(cpr_vaddr, dst, MMU_PAGESIZE); i_cpr_mapout(cpr_vaddr, 1); dst += MMU_PAGESIZE; } DEBUG1(errp("saved %d prom pages\n", ppage_count)); } /* * restore prom pages from kmem pages */ static void i_cpr_restore_ppages(void) { pfn_t *pphys, *plast; caddr_t src; dcache_flushall(); /* * map in each prom page and copy from a kmem page */ src = ppage_buf; plast = pphys_list + ppage_count; for (pphys = pphys_list; pphys < plast; pphys++) { i_cpr_mapin(cpr_vaddr, 1, *pphys); bcopy(src, cpr_vaddr, MMU_PAGESIZE); i_cpr_mapout(cpr_vaddr, 1); src += MMU_PAGESIZE; } dcache_flushall(); DEBUG1(errp("restored %d prom pages\n", ppage_count)); } /* * save/restore prom pages or free related allocs */ int i_cpr_prom_pages(int action) { int error; if (action == CPR_PROM_SAVE) { if (ppage_buf == NULL) { ASSERT(pphys_list == NULL); if (error = i_cpr_find_ppages()) return (error); i_cpr_save_ppages(); } } else if (action == CPR_PROM_RESTORE) { i_cpr_restore_ppages(); } else if (action == CPR_PROM_FREE) { if (pphys_list) { ASSERT(pphys_list_size); kmem_free(pphys_list, pphys_list_size); pphys_list = NULL; pphys_list_size = 0; } if (ppage_buf) { ASSERT(ppage_count); kmem_free(ppage_buf, mmu_ptob(ppage_count)); DEBUG1(errp("freed %d prom pages\n", ppage_count)); ppage_buf = NULL; ppage_count = 0; } } return (0); } /* * record tlb data for the nucleus, bigktsb's, and the cpr module; * this data is later used by cprboot to install dtlb/itlb entries. * when we jump into the cpr module during the resume phase, those * mappings are needed until switching to the kernel trap table. * to make the dtte/itte info available during resume, we need * the info recorded prior to saving sensitive pages, otherwise * all the data would appear as NULLs. */ static void i_cpr_save_tlbinfo(void) { cti_t cti; /* * during resume - shortly after jumping into the cpr module, * sfmmu_load_mmustate() will overwrite any dtlb entry at any * index used for TSBs; skip is set so that any saved tte will * target other tlb offsets and prevent being lost during * resume. now scan the dtlb and save locked entries, * then add entries for the tmp stack / data page and the * cpr thread structure. */ cti.dst = m_info.dtte; cti.tail = cti.dst + CPR_MAX_TLB; cti.reader = dtlb_rd_entry; cti.writer = NULL; cti.filter = i_cpr_lnb; cti.index = cpunodes[CPU->cpu_id].dtlb_size - 1; cti.skip = (1 << utsb_dtlb_ttenum); cti.skip |= (1 << utsb4m_dtlb_ttenum); i_cpr_scan_tlb(&cti); i_cpr_make_tte(&cti, &i_cpr_data_page, datava); i_cpr_make_tte(&cti, curthread, datava); /* * scan itlb and save locked entries; add an entry for * the first text page of the cpr module; cprboot will * jump to that page after restoring kernel pages. */ cti.dst = m_info.itte; cti.tail = cti.dst + CPR_MAX_TLB; cti.reader = itlb_rd_entry; cti.index = cpunodes[CPU->cpu_id].itlb_size - 1; cti.skip = 0; i_cpr_scan_tlb(&cti); i_cpr_make_tte(&cti, (void *)i_cpr_resume_setup, textva); } /* ARGSUSED */ int i_cpr_dump_setup(vnode_t *vp) { /* * zero out m_info and add info to dtte/itte arrays */ bzero(&m_info, sizeof (m_info)); i_cpr_save_tlbinfo(); return (0); } int i_cpr_is_supported(void) { char es_prop[] = "energystar-v2"; pnode_t node; int last; extern int cpr_supported_override; extern int cpr_platform_enable; /* * The next statement tests if a specific platform has turned off * cpr support. */ if (cpr_supported_override) return (0); /* * Do not inspect energystar-v* property if a platform has * specifically turned on cpr support */ if (cpr_platform_enable) return (1); node = prom_rootnode(); if (prom_getproplen(node, es_prop) != -1) return (1); last = strlen(es_prop) - 1; es_prop[last] = '3'; return (prom_getproplen(node, es_prop) != -1); } /* * the actual size of the statefile data isn't known until after all the * compressed pages are written; even the inode size doesn't reflect the * data size since there are usually many extra fs blocks. for recording * the actual data size, the first sector of the statefile is copied to * a tmp buf, and the copy is later updated and flushed to disk. */ int i_cpr_blockzero(char *base, char **bufpp, int *blkno, vnode_t *vp) { extern int cpr_flush_write(vnode_t *); static char cpr_sector[DEV_BSIZE]; cpr_ext bytes, *dst; /* * this routine is called after cdd_t and csu_md_t are copied * to cpr_buf; mini-hack alert: the save/update method creates * a dependency on the combined struct size being >= one sector * or DEV_BSIZE; since introduction in Sol2.7, csu_md_t size is * over 1K bytes and will probably grow with any changes. * * copy when vp is NULL, flush when non-NULL */ if (vp == NULL) { ASSERT((*bufpp - base) >= DEV_BSIZE); bcopy(base, cpr_sector, sizeof (cpr_sector)); return (0); } else { bytes = dbtob(*blkno); dst = &((cdd_t *)cpr_sector)->cdd_filesize; bcopy(&bytes, dst, sizeof (bytes)); bcopy(cpr_sector, base, sizeof (cpr_sector)); *bufpp = base + sizeof (cpr_sector); *blkno = cpr_statefile_offset(); DEBUG1(errp("statefile data size: %lld\n\n", bytes)); return (cpr_flush_write(vp)); } } /* * Allocate bitmaps according to the phys_install list. */ static int i_cpr_bitmap_setup(void) { struct memlist *pmem; cbd_t *dp, *tail; void *space; size_t size; /* * The number of bitmap descriptors will be the count of * phys_install ranges plus 1 for a trailing NULL struct. */ cpr_nbitmaps = 1; for (pmem = phys_install; pmem; pmem = pmem->next) cpr_nbitmaps++; if (cpr_nbitmaps > (CPR_MAX_BMDESC - 1)) { cpr_err(CE_WARN, "too many physical memory ranges %d, max %d", cpr_nbitmaps, CPR_MAX_BMDESC - 1); return (EFBIG); } /* Alloc an array of bitmap descriptors. */ dp = kmem_zalloc(cpr_nbitmaps * sizeof (*dp), KM_NOSLEEP); if (dp == NULL) { cpr_nbitmaps = 0; return (ENOMEM); } tail = dp + cpr_nbitmaps; CPR->c_bmda = dp; for (pmem = phys_install; pmem; pmem = pmem->next) { size = BITMAP_BYTES(pmem->size); space = kmem_zalloc(size * 2, KM_NOSLEEP); if (space == NULL) return (ENOMEM); ASSERT(dp < tail); dp->cbd_magic = CPR_BITMAP_MAGIC; dp->cbd_spfn = mmu_btop(pmem->address); dp->cbd_epfn = mmu_btop(pmem->address + pmem->size) - 1; dp->cbd_size = size; dp->cbd_reg_bitmap = (cpr_ptr)space; dp->cbd_vlt_bitmap = (cpr_ptr)((caddr_t)space + size); dp++; } /* set magic for the last descriptor */ ASSERT(dp == (tail - 1)); dp->cbd_magic = CPR_BITMAP_MAGIC; return (0); } void i_cpr_bitmap_cleanup(void) { cbd_t *dp; if (CPR->c_bmda == NULL) return; for (dp = CPR->c_bmda; dp->cbd_size; dp++) kmem_free((void *)dp->cbd_reg_bitmap, dp->cbd_size * 2); kmem_free(CPR->c_bmda, cpr_nbitmaps * sizeof (*CPR->c_bmda)); CPR->c_bmda = NULL; cpr_nbitmaps = 0; } /* * A "regular" and "volatile" bitmap are created for each range of * physical memory. The volatile maps are used to count and track pages * susceptible to heap corruption - caused by drivers that allocate mem * during VOP_DUMP(); the regular maps are used for all the other non- * susceptible pages. Before writing the bitmaps to the statefile, * each bitmap pair gets merged to simplify handling within cprboot. */ int i_cpr_alloc_bitmaps(void) { int err; memlist_read_lock(); err = i_cpr_bitmap_setup(); memlist_read_unlock(); if (err) i_cpr_bitmap_cleanup(); return (err); }