/* $NetBSD: pmap.c,v 1.16 2003/05/04 15:09:45 atatat Exp $ */ /* * Copyright (c) 2002, 2003 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by Andrew Brown. * * 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the NetBSD * Foundation, Inc. and its contributors. * 4. Neither the name of The NetBSD Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. 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 FOUNDATION 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 #ifndef lint __RCSID("$NetBSD: pmap.c,v 1.16 2003/05/04 15:09:45 atatat Exp $"); #endif #include #ifndef LOCKDEBUG #define VERSION regular #else /* LOCKDEBUG */ #define VERSION lockdebug #endif /* LOCKDEBUG */ #include "pmap.h" #include "main.h" static void dump_vm_anon(kvm_t *, struct vm_anon **, int); static char *findname(kvm_t *, struct kbit *, struct kbit *, struct kbit *, struct kbit *, struct kbit *); static int search_cache(kvm_t *, struct kbit *, char **, char *, size_t); /* when recursing, output is indented */ #define indent(n) ((n) * (recurse > 1 ? recurse - 1 : 0)) #define rwx (VM_PROT_READ | VM_PROT_WRITE | VM_PROT_EXECUTE) int heapfound; void PMAPFUNC(process_map,VERSION)(kvm_t *kd, struct kinfo_proc2 *proc, struct kbit *vmspace, const char *thing) { struct kbit kbit, *vm_map = &kbit; if (proc) { heapfound = 0; A(vmspace) = (u_long)proc->p_vmspace; S(vmspace) = sizeof(struct vmspace); thing = "proc->p_vmspace.vm_map"; } else if (S(vmspace) == -1) { heapfound = 0; /* A(vmspace) set by caller */ S(vmspace) = sizeof(struct vmspace); /* object identified by caller */ } else { heapfound = 1; /* but really, do kernels have a heap? */ A(vmspace) = 0; S(vmspace) = 0; thing = "kernel_map"; } S(vm_map) = sizeof(struct vm_map); if (S(vmspace) != 0) { KDEREF(kd, vmspace); A(vm_map) = A(vmspace) + offsetof(struct vmspace, vm_map); memcpy(D(vm_map, vm_map), &D(vmspace, vmspace)->vm_map, S(vm_map)); } else { memset(vmspace, 0, sizeof(*vmspace)); A(vm_map) = kernel_map_addr; KDEREF(kd, vm_map); } PMAPFUNC(dump_vm_map,VERSION)(kd, proc, vmspace, vm_map, thing); } void PMAPFUNC(dump_vm_map,VERSION)(kvm_t *kd, struct kinfo_proc2 *proc, struct kbit *vmspace, struct kbit *vm_map, const char *mname) { struct kbit kbit[2], *header, *vm_map_entry; struct vm_map_entry *last, *next; size_t total; u_long addr, end; if (S(vm_map) == -1) { heapfound = 1; S(vm_map) = sizeof(struct vm_map); KDEREF(kd, vm_map); } header = &kbit[0]; vm_map_entry = &kbit[1]; A(header) = 0; A(vm_map_entry) = 0; A(header) = A(vm_map) + offsetof(struct vm_map, header); S(header) = sizeof(struct vm_map_entry); memcpy(D(header, vm_map_entry), &D(vm_map, vm_map)->header, S(header)); if (S(vmspace) != 0 && (debug & PRINT_VMSPACE)) { printf("proc->p_vmspace %p = {", P(vmspace)); printf(" vm_refcnt = %d,", D(vmspace, vmspace)->vm_refcnt); printf(" vm_shm = %p,\n", D(vmspace, vmspace)->vm_shm); printf(" vm_rssize = %d,", D(vmspace, vmspace)->vm_rssize); printf(" vm_swrss = %d,", D(vmspace, vmspace)->vm_swrss); printf(" vm_tsize = %d,", D(vmspace, vmspace)->vm_tsize); printf(" vm_dsize = %d,\n", D(vmspace, vmspace)->vm_dsize); printf(" vm_ssize = %d,", D(vmspace, vmspace)->vm_ssize); printf(" vm_taddr = %p,", D(vmspace, vmspace)->vm_taddr); printf(" vm_daddr = %p,\n", D(vmspace, vmspace)->vm_daddr); printf(" vm_maxsaddr = %p,", D(vmspace, vmspace)->vm_maxsaddr); printf(" vm_minsaddr = %p }\n", D(vmspace, vmspace)->vm_minsaddr); } if (debug & PRINT_VM_MAP) { printf("%*s%s %p = {", indent(2), "", mname, P(vm_map)); printf(" pmap = %p,\n", D(vm_map, vm_map)->pmap); printf("%*s lock = ,", indent(2), ""); printf(" header = ,"); printf(" nentries = %d,\n", D(vm_map, vm_map)->nentries); printf("%*s size = %lx,", indent(2), "", D(vm_map, vm_map)->size); printf(" ref_count = %d,", D(vm_map, vm_map)->ref_count); printf(" ref_lock = ,\n"); printf("%*s hint = %p,", indent(2), "", D(vm_map, vm_map)->hint); printf(" hint_lock = ,\n"); printf("%*s first_free = %p,", indent(2), "", D(vm_map, vm_map)->first_free); printf(" flags = %x <%s%s%s%s%s%s%s >,\n", D(vm_map, vm_map)->flags, D(vm_map, vm_map)->flags & VM_MAP_PAGEABLE ? " PAGEABLE" : "", D(vm_map, vm_map)->flags & VM_MAP_INTRSAFE ? " INTRSAFE" : "", D(vm_map, vm_map)->flags & VM_MAP_WIREFUTURE ? " WIREFUTURE" : "", D(vm_map, vm_map)->flags & VM_MAP_BUSY ? " BUSY" : "", D(vm_map, vm_map)->flags & VM_MAP_WANTLOCK ? " WANTLOCK" : "", #ifdef VM_MAP_DYING D(vm_map, vm_map)->flags & VM_MAP_DYING ? " DYING" : #endif "", #ifdef VM_MAP_TOPDOWN D(vm_map, vm_map)->flags & VM_MAP_TOPDOWN ? " TOPDOWN" : #endif ""); printf("%*s flags_lock = ,", indent(2), ""); printf(" timestamp = %u }\n", D(vm_map, vm_map)->timestamp); } if (print_ddb) { const char *name = mapname(P(vm_map)); printf("%*s%s %p: [0x%lx->0x%lx]\n", indent(2), "", recurse < 2 ? "MAP" : "SUBMAP", P(vm_map), D(vm_map, vm_map)->min_offset, D(vm_map, vm_map)->max_offset); printf("\t%*s#ent=%d, sz=%ld, ref=%d, version=%d, flags=0x%x\n", indent(2), "", D(vm_map, vm_map)->nentries, D(vm_map, vm_map)->size, D(vm_map, vm_map)->ref_count, D(vm_map, vm_map)->timestamp, D(vm_map, vm_map)->flags); printf("\t%*spmap=%p(resident=)\n", indent(2), "", D(vm_map, vm_map)->pmap); if (verbose && name != NULL) printf("\t%*s([ %s ])\n", indent(2), "", name); } PMAPFUNC(dump_vm_map_entry,VERSION)(kd, proc, vmspace, header, 1); /* * we're not recursing into a submap, so print headers */ if (recurse < 2) { /* headers */ #ifdef DISABLED_HEADERS if (print_map) printf("%-*s %-*s rwx RWX CPY NCP I W A\n", (int)sizeof(long) * 2 + 2, "Start", (int)sizeof(long) * 2 + 2, "End"); if (print_maps) printf("%-*s %-*s rwxp %-*s Dev Inode File\n", (int)sizeof(long) * 2 + 0, "Start", (int)sizeof(long) * 2 + 0, "End", (int)sizeof(long) * 2 + 0, "Offset"); if (print_solaris) printf("%-*s %*s Protection File\n", (int)sizeof(long) * 2 + 0, "Start", (int)sizeof(int) * 2 - 1, "Size "); #endif if (print_all) printf("%-*s %-*s %*s %-*s rwxpc RWX I/W/A Dev %*s" " - File\n", (int)sizeof(long) * 2, "Start", (int)sizeof(long) * 2, "End", (int)sizeof(int) * 2, "Size ", (int)sizeof(long) * 2, "Offset", (int)sizeof(int) * 2, "Inode"); } /* these are the "sub entries" */ total = 0; next = D(header, vm_map_entry)->next; last = P(header); end = 0; while (next != 0 && next != last) { addr = (u_long)next; A(vm_map_entry) = addr; S(vm_map_entry) = sizeof(struct vm_map_entry); KDEREF(kd, vm_map_entry); next = D(vm_map_entry, vm_map_entry)->next; if (end == 0) end = D(vm_map_entry, vm_map_entry)->start; else if (verbose > 1 && end != D(vm_map_entry, vm_map_entry)->start) printf("%*s[%lu pages / %luK]\n", indent(2), "", (D(vm_map_entry, vm_map_entry)->start - end) / page_size, (D(vm_map_entry, vm_map_entry)->start - end) / 1024); total += PMAPFUNC(dump_vm_map_entry,VERSION)(kd, proc, vmspace, vm_map_entry, 0); end = D(vm_map_entry, vm_map_entry)->end; } /* * we're not recursing into a submap, so print totals */ if (recurse < 2) { if (print_solaris) printf("%-*s %8luK\n", (int)sizeof(void *) * 2 - 2, " total", (unsigned long)total); if (print_all) printf("%-*s %9luk\n", (int)sizeof(void *) * 4 - 1, " total", (unsigned long)total); } } size_t PMAPFUNC(dump_vm_map_entry,VERSION)(kvm_t *kd, struct kinfo_proc2 *proc, struct kbit *vmspace, struct kbit *vm_map_entry, int ishead) { struct kbit kbit[3]; struct kbit *uvm_obj, *vp, *vfs; struct vm_map_entry *vme; size_t sz; char *name; dev_t dev; ino_t inode; if (S(vm_map_entry) == -1) { heapfound = 1; S(vm_map_entry) = sizeof(struct vm_map_entry); KDEREF(kd, vm_map_entry); } uvm_obj = &kbit[0]; vp = &kbit[1]; vfs = &kbit[2]; A(uvm_obj) = 0; A(vp) = 0; A(vfs) = 0; vme = D(vm_map_entry, vm_map_entry); if ((ishead && (debug & PRINT_VM_MAP_HEADER)) || (!ishead && (debug & PRINT_VM_MAP_ENTRY))) { printf("%*s%s %p = {", indent(2), "", ishead ? "vm_map.header" : "vm_map_entry", P(vm_map_entry)); printf(" prev = %p,", vme->prev); printf(" next = %p,\n", vme->next); printf("%*s start = %lx,", indent(2), "", vme->start); printf(" end = %lx,", vme->end); printf(" object.uvm_obj/sub_map = %p,\n", vme->object.uvm_obj); printf("%*s offset = %" PRIx64 ",", indent(2), "", vme->offset); printf(" etype = %x <%s%s%s%s >,", vme->etype, UVM_ET_ISOBJ(vme) ? " OBJ" : "", UVM_ET_ISSUBMAP(vme) ? " SUBMAP" : "", UVM_ET_ISCOPYONWRITE(vme) ? " COW" : "", UVM_ET_ISNEEDSCOPY(vme) ? " NEEDSCOPY" : ""); printf(" protection = %x,\n", vme->protection); printf("%*s max_protection = %x,", indent(2), "", vme->max_protection); printf(" inheritance = %d,", vme->inheritance); printf(" wired_count = %d,\n", vme->wired_count); printf("%*s aref = { ar_pageoff = %x, ar_amap = %p },", indent(2), "", vme->aref.ar_pageoff, vme->aref.ar_amap); printf(" advice = %d,\n", vme->advice); printf("%*s flags = %x <%s%s > }\n", indent(2), "", vme->flags, vme->flags & UVM_MAP_STATIC ? " STATIC" : "", vme->flags & UVM_MAP_KMEM ? " KMEM" : ""); } if ((debug & PRINT_VM_AMAP) && (vme->aref.ar_amap != NULL)) { struct kbit akbit, *amap; amap = &akbit; P(amap) = vme->aref.ar_amap; S(amap) = sizeof(struct vm_amap); KDEREF(kd, amap); PMAPFUNC(dump_amap,VERSION)(kd, amap); } if (ishead) return (0); A(vp) = 0; A(uvm_obj) = 0; if (vme->object.uvm_obj != NULL) { P(uvm_obj) = vme->object.uvm_obj; S(uvm_obj) = sizeof(struct uvm_object); KDEREF(kd, uvm_obj); if (UVM_ET_ISOBJ(vme) && UVM_OBJ_IS_VNODE(D(uvm_obj, uvm_object))) { P(vp) = P(uvm_obj); S(vp) = sizeof(struct vnode); KDEREF(kd, vp); } } A(vfs) = NULL; if (P(vp) != NULL && D(vp, vnode)->v_mount != NULL) { P(vfs) = D(vp, vnode)->v_mount; S(vfs) = sizeof(struct mount); KDEREF(kd, vfs); D(vp, vnode)->v_mount = D(vfs, mount); } /* * dig out the device number and inode number from certain * file system types. */ #define V_DATA_IS(vp, type, d, i) do { \ struct kbit data; \ P(&data) = D(vp, vnode)->v_data; \ S(&data) = sizeof(*D(&data, type)); \ KDEREF(kd, &data); \ dev = D(&data, type)->d; \ inode = D(&data, type)->i; \ } while (0/*CONSTCOND*/) dev = 0; inode = 0; if (A(vp) && D(vp, vnode)->v_type == VREG && D(vp, vnode)->v_data != NULL) { switch (D(vp, vnode)->v_tag) { case VT_UFS: case VT_LFS: case VT_EXT2FS: V_DATA_IS(vp, inode, i_dev, i_number); break; case VT_ISOFS: V_DATA_IS(vp, iso_node, i_dev, i_number); break; case VT_NON: case VT_NFS: case VT_MFS: case VT_MSDOSFS: case VT_LOFS: case VT_FDESC: case VT_PORTAL: case VT_NULL: case VT_UMAP: case VT_KERNFS: case VT_PROCFS: case VT_AFS: case VT_UNION: case VT_ADOSFS: case VT_CODA: case VT_FILECORE: case VT_NTFS: case VT_VFS: case VT_OVERLAY: case VT_SMBFS: break; } } name = findname(kd, vmspace, vm_map_entry, vp, vfs, uvm_obj); if (print_map) { printf("%*s0x%lx 0x%lx %c%c%c %c%c%c %s %s %d %d %d", indent(2), "", vme->start, vme->end, (vme->protection & VM_PROT_READ) ? 'r' : '-', (vme->protection & VM_PROT_WRITE) ? 'w' : '-', (vme->protection & VM_PROT_EXECUTE) ? 'x' : '-', (vme->max_protection & VM_PROT_READ) ? 'r' : '-', (vme->max_protection & VM_PROT_WRITE) ? 'w' : '-', (vme->max_protection & VM_PROT_EXECUTE) ? 'x' : '-', UVM_ET_ISCOPYONWRITE(vme) ? "COW" : "NCOW", UVM_ET_ISNEEDSCOPY(vme) ? "NC" : "NNC", vme->inheritance, vme->wired_count, vme->advice); if (verbose) { if (inode) printf(" %d,%d %d", major(dev), minor(dev), inode); if (name[0]) printf(" %s", name); } printf("\n"); } if (print_maps) { printf("%*s%0*lx-%0*lx %c%c%c%c %0*" PRIx64 " %02x:%02x %d %s\n", indent(2), "", (int)sizeof(void *) * 2, vme->start, (int)sizeof(void *) * 2, vme->end, (vme->protection & VM_PROT_READ) ? 'r' : '-', (vme->protection & VM_PROT_WRITE) ? 'w' : '-', (vme->protection & VM_PROT_EXECUTE) ? 'x' : '-', UVM_ET_ISCOPYONWRITE(vme) ? 'p' : 's', (int)sizeof(void *) * 2, vme->offset, major(dev), minor(dev), inode, (name[0] != ' ') || verbose ? name : ""); } if (print_ddb) { printf("%*s - %p: 0x%lx->0x%lx: obj=%p/0x%" PRIx64 ", amap=%p/%d\n", indent(2), "", P(vm_map_entry), vme->start, vme->end, vme->object.uvm_obj, vme->offset, vme->aref.ar_amap, vme->aref.ar_pageoff); printf("\t%*ssubmap=%c, cow=%c, nc=%c, prot(max)=%d/%d, inh=%d, " "wc=%d, adv=%d\n", indent(2), "", UVM_ET_ISSUBMAP(vme) ? 'T' : 'F', UVM_ET_ISCOPYONWRITE(vme) ? 'T' : 'F', UVM_ET_ISNEEDSCOPY(vme) ? 'T' : 'F', vme->protection, vme->max_protection, vme->inheritance, vme->wired_count, vme->advice); if (verbose) { printf("\t%*s", indent(2), ""); if (inode) printf("(dev=%d,%d ino=%d [%s] [%p])\n", major(dev), minor(dev), inode, name, P(vp)); else if (name[0] == ' ') printf("(%s)\n", &name[2]); else printf("(%s)\n", name); } } sz = 0; if (print_solaris) { char prot[30]; prot[0] = '\0'; prot[1] = '\0'; if (vme->protection & VM_PROT_READ) strcat(prot, "/read"); if (vme->protection & VM_PROT_WRITE) strcat(prot, "/write"); if (vme->protection & VM_PROT_EXECUTE) strcat(prot, "/exec"); sz = (size_t)((vme->end - vme->start) / 1024); printf("%*s%0*lX %6luK %-15s %s\n", indent(2), "", (int)sizeof(void *) * 2, (unsigned long)vme->start, (unsigned long)sz, &prot[1], name); } if (print_all) { sz = (size_t)((vme->end - vme->start) / 1024); printf(A(vp) ? "%*s%0*lx-%0*lx %7luk %0*" PRIx64 " %c%c%c%c%c (%c%c%c) %d/%d/%d %02d:%02d %7d - %s [%p]\n" : "%*s%0*lx-%0*lx %7luk %0*" PRIx64 " %c%c%c%c%c (%c%c%c) %d/%d/%d %02d:%02d %7d - %s\n", indent(2), "", (int)sizeof(void *) * 2, vme->start, (int)sizeof(void *) * 2, vme->end - (vme->start != vme->end ? 1 : 0), (unsigned long)sz, (int)sizeof(void *) * 2, vme->offset, (vme->protection & VM_PROT_READ) ? 'r' : '-', (vme->protection & VM_PROT_WRITE) ? 'w' : '-', (vme->protection & VM_PROT_EXECUTE) ? 'x' : '-', UVM_ET_ISCOPYONWRITE(vme) ? 'p' : 's', UVM_ET_ISNEEDSCOPY(vme) ? '+' : '-', (vme->max_protection & VM_PROT_READ) ? 'r' : '-', (vme->max_protection & VM_PROT_WRITE) ? 'w' : '-', (vme->max_protection & VM_PROT_EXECUTE) ? 'x' : '-', vme->inheritance, vme->wired_count, vme->advice, major(dev), minor(dev), inode, name, P(vp)); } /* no access allowed, don't count space */ if ((vme->protection & rwx) == 0) sz = 0; if (recurse && UVM_ET_ISSUBMAP(vme)) { struct kbit mkbit, *submap; recurse++; submap = &mkbit; P(submap) = vme->object.sub_map; S(submap) = sizeof(*vme->object.sub_map); KDEREF(kd, submap); PMAPFUNC(dump_vm_map,VERSION)(kd, proc, vmspace, submap, "submap"); recurse--; } return (sz); } void PMAPFUNC(dump_amap,VERSION)(kvm_t *kd, struct kbit *amap) { struct vm_anon **am_anon; int *am_slots; int *am_bckptr; int *am_ppref; size_t i, r, l, e; if (S(amap) == -1) { heapfound = 1; S(amap) = sizeof(struct vm_amap); KDEREF(kd, amap); } printf("%*s amap %p = { am_l = , am_ref = %d, " "am_flags = %x,\n" "%*s am_maxslot = %d, am_nslot = %d, am_nused = %d, " "am_slots = %p,\n" "%*s am_bckptr = %p, am_anon = %p, am_ppref = %p }\n", indent(2), "", P(amap), D(amap, amap)->am_ref, D(amap, amap)->am_flags, indent(2), "", D(amap, amap)->am_maxslot, D(amap, amap)->am_nslot, D(amap, amap)->am_nused, D(amap, amap)->am_slots, indent(2), "", D(amap, amap)->am_bckptr, D(amap, amap)->am_anon, D(amap, amap)->am_ppref); if (!(debug & DUMP_VM_AMAP_DATA)) return; /* * Assume that sizeof(struct vm_anon *) >= sizeof(size_t) and * allocate that amount of space. */ l = sizeof(struct vm_anon *) * D(amap, amap)->am_maxslot; am_anon = malloc(l); _KDEREF(kd, (u_long)D(amap, amap)->am_anon, am_anon, l); l = sizeof(int) * D(amap, amap)->am_maxslot; am_bckptr = malloc(l); _KDEREF(kd, (u_long)D(amap, amap)->am_bckptr, am_bckptr, l); l = sizeof(int) * D(amap, amap)->am_maxslot; am_slots = malloc(l); _KDEREF(kd, (u_long)D(amap, amap)->am_slots, am_slots, l); if (D(amap, amap)->am_ppref != NULL && D(amap, amap)->am_ppref != PPREF_NONE) { l = sizeof(int) * D(amap, amap)->am_maxslot; am_ppref = malloc(l); _KDEREF(kd, (u_long)D(amap, amap)->am_ppref, am_ppref, l); } else { am_ppref = NULL; } printf(" page# %9s %8s", "am_bckptr", "am_slots"); if (am_ppref) printf(" %8s ", "am_ppref"); printf(" %10s\n", "am_anon"); l = 0; e = verbose > 1 ? D(amap, amap)->am_maxslot : D(amap, amap)->am_nslot; for (i = 0; i < e; i++) { printf(" %4lx", (unsigned long)i); if (am_anon[i] || verbose > 1) printf(" %8x", am_bckptr[i]); else printf(" %8s", "-"); if (i < D(amap, amap)->am_nused || verbose > 1) printf(" %8x", am_slots[i]); else printf(" %8s", "-"); if (am_ppref) { if (l == 0 || r || verbose > 1) printf(" %8d", am_ppref[i]); else printf(" %8s", "-"); r = 0; if (l == 0) { if (am_ppref[i] > 0) { r = am_ppref[i] - 1; l = 1; } else { r = -am_ppref[i] - 1; l = am_ppref[i + 1]; } printf(" (%4ld @ %4ld)", (long)l, (long)r); r = (l > 1) ? 1 : 0; } else printf(" "); l--; } dump_vm_anon(kd, am_anon, i); } free(am_anon); free(am_bckptr); free(am_slots); if (am_ppref) free(am_ppref); } static void dump_vm_anon(kvm_t *kd, struct vm_anon **alist, int i) { printf(" %10p", alist[i]); if (debug & PRINT_VM_ANON) { struct kbit kbit, *anon = &kbit; A(anon) = (u_long)alist[i]; S(anon) = sizeof(struct vm_anon); if (A(anon) == 0) { printf(" = { }\n"); return; } else KDEREF(kd, anon); printf(" = { an_ref = %d, an_lock = , an_nxt/an_page = %p, an_swslot = %d }", D(anon, anon)->an_ref, D(anon, anon)->u.an_nxt, D(anon, anon)->an_swslot); } printf("\n"); } static char* findname(kvm_t *kd, struct kbit *vmspace, struct kbit *vm_map_entry, struct kbit *vp, struct kbit *vfs, struct kbit *uvm_obj) { static char buf[1024], *name; struct vm_map_entry *vme; size_t l; vme = D(vm_map_entry, vm_map_entry); if (UVM_ET_ISOBJ(vme)) { if (A(vfs)) { l = (unsigned)strlen(D(vfs, mount)->mnt_stat.f_mntonname); switch (search_cache(kd, vp, &name, buf, sizeof(buf))) { case 0: /* found something */ name--; *name = '/'; /*FALLTHROUGH*/ case 2: /* found nothing */ name -= 5; memcpy(name, " -?- ", (size_t)5); name -= l; memcpy(name, D(vfs, mount)->mnt_stat.f_mntonname, l); break; case 1: /* all is well */ name--; *name = '/'; if (l != 1) { name -= l; memcpy(name, D(vfs, mount)->mnt_stat.f_mntonname, l); } break; } } else if (UVM_OBJ_IS_DEVICE(D(uvm_obj, uvm_object))) { struct kbit kdev; dev_t dev; P(&kdev) = P(uvm_obj); S(&kdev) = sizeof(struct uvm_device); KDEREF(kd, &kdev); dev = D(&kdev, uvm_device)->u_device; name = devname(dev, S_IFCHR); if (name != NULL) snprintf(buf, sizeof(buf), "/dev/%s", name); else snprintf(buf, sizeof(buf), " [ device %d,%d ]", major(dev), minor(dev)); name = buf; } else if (UVM_OBJ_IS_AOBJ(D(uvm_obj, uvm_object))) name = " [ uvm_aobj ]"; else if (UVM_OBJ_IS_UBCPAGER(D(uvm_obj, uvm_object))) name = " [ ubc_pager ]"; else if (UVM_OBJ_IS_VNODE(D(uvm_obj, uvm_object))) name = " [ ?VNODE? ]"; else { snprintf(buf, sizeof(buf), " [ ?? %p ?? ]", D(uvm_obj, uvm_object)->pgops); name = buf; } } else if (D(vmspace, vmspace)->vm_maxsaddr <= (caddr_t)vme->start && (D(vmspace, vmspace)->vm_maxsaddr + (size_t)maxssiz) >= (caddr_t)vme->end) name = " [ stack ]"; else if (!heapfound && (vme->protection & rwx) == rwx && vme->start >= (u_long)D(vmspace, vmspace)->vm_daddr) { heapfound = 1; name = " [ heap ]"; } else if (UVM_ET_ISSUBMAP(vme)) { const char *sub = mapname(vme->object.sub_map); snprintf(buf, sizeof(buf), " [ %s ]", sub ? sub : "(submap)"); name = buf; } else name = " [ anon ]"; return (name); } static int search_cache(kvm_t *kd, struct kbit *vp, char **name, char *buf, size_t blen) { char *o, *e; struct cache_entry *ce; struct kbit svp; u_long cid; if (nchashtbl == NULL) load_name_cache(kd); P(&svp) = P(vp); S(&svp) = sizeof(struct vnode); cid = D(vp, vnode)->v_id; e = &buf[blen - 1]; o = e; do { LIST_FOREACH(ce, &lcache, ce_next) if (ce->ce_vp == P(&svp) && ce->ce_cid == cid) break; if (ce && ce->ce_vp == P(&svp) && ce->ce_cid == cid) { if (o != e) *(--o) = '/'; o -= ce->ce_nlen; memcpy(o, ce->ce_name, (unsigned)ce->ce_nlen); P(&svp) = ce->ce_pvp; cid = ce->ce_pcid; } else break; } while (1/*CONSTCOND*/); *e = '\0'; *name = o; if (e == o) return (2); KDEREF(kd, &svp); return (D(&svp, vnode)->v_flag & VROOT); }