/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (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 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #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 int vfs_walk_init(mdb_walk_state_t *wsp) { if (wsp->walk_addr == NULL && mdb_readvar(&wsp->walk_addr, "rootvfs") == -1) { mdb_warn("failed to read 'rootvfs'"); return (WALK_ERR); } wsp->walk_data = (void *)wsp->walk_addr; return (WALK_NEXT); } int vfs_walk_step(mdb_walk_state_t *wsp) { vfs_t vfs; int status; if (mdb_vread(&vfs, sizeof (vfs), wsp->walk_addr) == -1) { mdb_warn("failed to read vfs_t at %p", wsp->walk_addr); return (WALK_DONE); } status = wsp->walk_callback(wsp->walk_addr, &vfs, wsp->walk_cbdata); if (vfs.vfs_next == wsp->walk_data) return (WALK_DONE); wsp->walk_addr = (uintptr_t)vfs.vfs_next; return (status); } /* * Utility routine to read in a filesystem name given a vfs pointer. If * no vfssw entry for the vfs is available (as is the case with some pseudo- * filesystems), we check against some known problem fs's: doorfs and * portfs. If that fails, we try to guess the filesystem name using * symbol names. fsname should be a buffer of size _ST_FSTYPSZ. */ static int read_fsname(uintptr_t vfsp, char *fsname) { vfs_t vfs; struct vfssw vfssw_entry; GElf_Sym vfssw_sym, test_sym; char testname[MDB_SYM_NAMLEN]; if (mdb_vread(&vfs, sizeof (vfs), vfsp) == -1) { mdb_warn("failed to read vfs %p", vfsp); return (-1); } if (mdb_lookup_by_name("vfssw", &vfssw_sym) == -1) { mdb_warn("failed to find vfssw"); return (-1); } /* * vfssw is an array; we need vfssw[vfs.vfs_fstype]. */ if (mdb_vread(&vfssw_entry, sizeof (vfssw_entry), vfssw_sym.st_value + (sizeof (struct vfssw) * vfs.vfs_fstype)) == -1) { mdb_warn("failed to read vfssw index %d", vfs.vfs_fstype); return (-1); } if (vfs.vfs_fstype != 0) { if (mdb_readstr(fsname, _ST_FSTYPSZ, (uintptr_t)vfssw_entry.vsw_name) == -1) { mdb_warn("failed to find fs name %p", vfssw_entry.vsw_name); return (-1); } return (0); } /* * Do precise detection for certain filesystem types that we * know do not appear in vfssw[], and that we depend upon in other * parts of the code: doorfs and portfs. */ if (mdb_lookup_by_name("door_vfs", &test_sym) != -1) { if (test_sym.st_value == vfsp) { strcpy(fsname, "doorfs"); return (0); } } if (mdb_lookup_by_name("port_vfs", &test_sym) != -1) { if (test_sym.st_value == vfsp) { strcpy(fsname, "portfs"); return (0); } } /* * Heuristic detection for other filesystems that don't have a * vfssw[] entry. These tend to be named _vfs, so we do a * lookup_by_addr and see if we find a symbol of that name. */ if (mdb_lookup_by_addr(vfsp, MDB_SYM_EXACT, testname, sizeof (testname), &test_sym) != -1) { if ((strlen(testname) > 4) && (strcmp(testname + strlen(testname) - 4, "_vfs") == 0)) { testname[strlen(testname) - 4] = '\0'; strncpy(fsname, testname, _ST_FSTYPSZ); return (0); } } mdb_warn("unknown filesystem type for vfs %p", vfsp); return (-1); } /* * Column widths for mount point display in ::fsinfo output. */ #ifdef _LP64 #define FSINFO_MNTLEN 48 #else #define FSINFO_MNTLEN 56 #endif /* ARGSUSED */ int fsinfo(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { vfs_t vfs; int len; int opt_v = 0; char buf[MAXPATHLEN]; char fsname[_ST_FSTYPSZ]; mntopt_t *mntopts; size_t size; int i; int first = 1; char opt[MAX_MNTOPT_STR]; uintptr_t global_zone; if (!(flags & DCMD_ADDRSPEC)) { if (mdb_walk_dcmd("vfs", "fsinfo", argc, argv) == -1) { mdb_warn("failed to walk file system list"); return (DCMD_ERR); } return (DCMD_OK); } if (mdb_getopts(argc, argv, 'v', MDB_OPT_SETBITS, TRUE, &opt_v, NULL) != argc) return (DCMD_USAGE); if (DCMD_HDRSPEC(flags)) mdb_printf("%%?s %-15s %s%\n", "VFSP", "FS", "MOUNT"); if (mdb_vread(&vfs, sizeof (vfs), addr) == -1) { mdb_warn("failed to read vfs_t %p", addr); return (DCMD_ERR); } if ((len = mdb_read_refstr((uintptr_t)vfs.vfs_mntpt, buf, sizeof (buf))) <= 0) strcpy(buf, "??"); else if (!opt_v && (len >= FSINFO_MNTLEN)) /* * In normal mode, we truncate the path to keep the output * clean. In -v mode, we just print the full path. */ strcpy(&buf[FSINFO_MNTLEN - 4], "..."); if (read_fsname(addr, fsname) == -1) return (DCMD_ERR); mdb_printf("%0?p %-15s %s\n", addr, fsname, buf); if (!opt_v) return (DCMD_OK); /* * Print 'resource' string; this shows what we're mounted upon. */ if (mdb_read_refstr((uintptr_t)vfs.vfs_resource, buf, MAXPATHLEN) <= 0) strcpy(buf, "??"); mdb_printf("%?s %s\n", "R:", buf); /* * Print mount options array; it sucks to be a mimic, but we copy * the same logic as in mntvnops.c for adding zone= tags, and we * don't bother with the obsolete dev= option. */ size = vfs.vfs_mntopts.mo_count * sizeof (mntopt_t); mntopts = mdb_alloc(size, UM_SLEEP | UM_GC); if (mdb_vread(mntopts, size, (uintptr_t)vfs.vfs_mntopts.mo_list) == -1) { mdb_warn("failed to read mntopts %p", vfs.vfs_mntopts.mo_list); return (DCMD_ERR); } for (i = 0; i < vfs.vfs_mntopts.mo_count; i++) { if (mntopts[i].mo_flags & MO_SET) { if (mdb_readstr(opt, sizeof (opt), (uintptr_t)mntopts[i].mo_name) == -1) { mdb_warn("failed to read mntopt name %p", mntopts[i].mo_name); return (DCMD_ERR); } if (first) { mdb_printf("%?s ", "O:"); first = 0; } else { mdb_printf(","); } mdb_printf("%s", opt); if (mntopts[i].mo_flags & MO_HASVALUE) { if (mdb_readstr(opt, sizeof (opt), (uintptr_t)mntopts[i].mo_arg) == -1) { mdb_warn("failed to read mntopt " "value %p", mntopts[i].mo_arg); return (DCMD_ERR); } mdb_printf("=%s", opt); } } } if (mdb_readvar(&global_zone, "global_zone") == -1) { mdb_warn("failed to locate global_zone"); return (DCMD_ERR); } if ((vfs.vfs_zone != NULL) && ((uintptr_t)vfs.vfs_zone != global_zone)) { zone_t z; if (mdb_vread(&z, sizeof (z), (uintptr_t)vfs.vfs_zone) == -1) { mdb_warn("failed to read zone"); return (DCMD_ERR); } /* * zone names are much shorter than MAX_MNTOPT_STR */ if (mdb_readstr(opt, sizeof (opt), (uintptr_t)z.zone_name) == -1) { mdb_warn("failed to read zone name"); return (DCMD_ERR); } if (first) { mdb_printf("%?s ", "O:"); } else { mdb_printf(","); } mdb_printf("zone=%s", opt); } return (DCMD_OK); } #define REALVP_DONE 0 #define REALVP_ERR 1 #define REALVP_CONTINUE 2 static int next_realvp(uintptr_t invp, struct vnode *outvn, uintptr_t *outvp) { char fsname[_ST_FSTYPSZ]; *outvp = invp; if (mdb_vread(outvn, sizeof (struct vnode), invp) == -1) { mdb_warn("failed to read vnode at %p", invp); return (REALVP_ERR); } if (read_fsname((uintptr_t)outvn->v_vfsp, fsname) == -1) return (REALVP_ERR); /* * We know how to do 'realvp' for as many filesystems as possible; * for all other filesystems, we assume that the vp we are given * is the realvp. In the kernel, a realvp operation will sometimes * dig through multiple layers. Here, we only fetch the pointer * to the next layer down. This allows dcmds to print out the * various layers. */ if (strcmp(fsname, "fifofs") == 0) { fifonode_t fn; if (mdb_vread(&fn, sizeof (fn), (uintptr_t)outvn->v_data) == -1) { mdb_warn("failed to read fifonode"); return (REALVP_ERR); } *outvp = (uintptr_t)fn.fn_realvp; } else if (strcmp(fsname, "namefs") == 0) { struct namenode nn; if (mdb_vread(&nn, sizeof (nn), (uintptr_t)outvn->v_data) == -1) { mdb_warn("failed to read namenode"); return (REALVP_ERR); } *outvp = (uintptr_t)nn.nm_filevp; } else if (outvn->v_type == VSOCK && outvn->v_stream != NULL) { struct stdata stream; /* * Sockets have a strange and different layering scheme; we * hop over into the sockfs vnode (accessible via the stream * head) if possible. */ if (mdb_vread(&stream, sizeof (stream), (uintptr_t)outvn->v_stream) == -1) { mdb_warn("failed to read stream data"); return (REALVP_ERR); } *outvp = (uintptr_t)stream.sd_vnode; } if (*outvp == invp || *outvp == NULL) return (REALVP_DONE); return (REALVP_CONTINUE); } static void pfiles_print_addr(struct sockaddr *addr) { struct sockaddr_in *s_in; struct sockaddr_un *s_un; struct sockaddr_in6 *s_in6; in_port_t port; switch (addr->sa_family) { case AF_INET: /* LINTED: alignment */ s_in = (struct sockaddr_in *)addr; mdb_nhconvert(&port, &s_in->sin_port, sizeof (port)); mdb_printf("AF_INET %I %d ", s_in->sin_addr.s_addr, port); break; case AF_INET6: /* LINTED: alignment */ s_in6 = (struct sockaddr_in6 *)addr; mdb_nhconvert(&port, &s_in6->sin6_port, sizeof (port)); mdb_printf("AF_INET6 %N %d ", &(s_in6->sin6_addr), port); break; case AF_UNIX: s_un = (struct sockaddr_un *)addr; mdb_printf("AF_UNIX %s ", s_un->sun_path); break; default: mdb_printf("AF_?? (%d) ", addr->sa_family); break; } } static int pfiles_get_sonode(vnode_t *v_sock, struct sonode *sonode) { if (mdb_vread(sonode, sizeof (struct sonode), (uintptr_t)v_sock->v_data) == -1) { mdb_warn("failed to read sonode"); return (-1); } return (0); } static int pfiles_get_tpi_sonode(vnode_t *v_sock, sotpi_sonode_t *sotpi_sonode) { struct stdata stream; if (mdb_vread(&stream, sizeof (stream), (uintptr_t)v_sock->v_stream) == -1) { mdb_warn("failed to read stream data"); return (-1); } if (mdb_vread(v_sock, sizeof (vnode_t), (uintptr_t)stream.sd_vnode) == -1) { mdb_warn("failed to read stream vnode"); return (-1); } if (mdb_vread(sotpi_sonode, sizeof (sotpi_sonode_t), (uintptr_t)v_sock->v_data) == -1) { mdb_warn("failed to read sotpi_sonode"); return (-1); } return (0); } /* * Do some digging to get a reasonable pathname for this vnode. 'path' * should point at a buffer of MAXPATHLEN in size. */ static int pfiles_dig_pathname(uintptr_t vp, char *path) { vnode_t v; bzero(path, MAXPATHLEN); if (mdb_vread(&v, sizeof (v), vp) == -1) { mdb_warn("failed to read vnode"); return (-1); } if (v.v_path == NULL) { /* * fifo's and doors are special. Some have pathnames, and * some do not. And for these, it is pointless to go off to * mdb_vnode2path, which is very slow. * * Event ports never have a pathname. */ if (v.v_type == VFIFO || v.v_type == VDOOR || v.v_type == VPORT) return (0); /* * For sockets, we won't find a path unless we print the path * associated with transport's STREAM device. */ if (v.v_type == VSOCK) { struct sonode sonode; struct sockparams sockparams; if (pfiles_get_sonode(&v, &sonode) == -1) { return (-1); } if (mdb_vread(&sockparams, sizeof (sockparams), (uintptr_t)sonode.so_sockparams) == -1) { mdb_warn("failed to read sockparams"); return (-1); } if (!SOCK_IS_NONSTR(&sonode)) { vp = (uintptr_t) sockparams.sp_sdev_info.sd_vnode; } else { vp = NULL; } } } /* * mdb_vnode2path will print an error for us as needed, but not * finding a pathname is not really an error, so we plow on. */ (void) mdb_vnode2path(vp, path, MAXPATHLEN); /* * A common problem is that device pathnames are prefixed with * /dev/../devices/. We just clean those up slightly: * /dev/../devices/ --> /devices/ * /dev/pts/../../devices/ --> /devices/ */ if (strncmp("/dev/../devices/", path, strlen("/dev/../devices/")) == 0) strcpy(path, path + 7); if (strncmp("/dev/pts/../../devices/", path, strlen("/dev/pts/../../devices/")) == 0) strcpy(path, path + 14); return (0); } const struct fs_type { int type; const char *name; } fs_types[] = { { VNON, "NON" }, { VREG, "REG" }, { VDIR, "DIR" }, { VBLK, "BLK" }, { VCHR, "CHR" }, { VLNK, "LNK" }, { VFIFO, "FIFO" }, { VDOOR, "DOOR" }, { VPROC, "PROC" }, { VSOCK, "SOCK" }, { VPORT, "PORT" }, { VBAD, "BAD" } }; #define NUM_FS_TYPES (sizeof (fs_types) / sizeof (struct fs_type)) struct pfiles_cbdata { int opt_p; int fd; }; #define list_d2l(a, obj) ((list_node_t *)(((char *)obj) + (a)->list_offset)) #define list_object(a, node) ((void *)(((char *)node) - (a)->list_offset)) /* * SCTP interface for geting the first source address of a sctp_t. */ int sctp_getsockaddr(sctp_t *sctp, struct sockaddr *addr) { int err = -1; int i; int l; sctp_saddr_ipif_t *pobj; sctp_saddr_ipif_t obj; size_t added = 0; sin6_t *sin6; sin_t *sin4; int scanned = 0; boolean_t skip_lback = B_FALSE; conn_t *connp = sctp->sctp_connp; addr->sa_family = connp->conn_family; if (sctp->sctp_nsaddrs == 0) goto done; /* * Skip loopback addresses for non-loopback assoc. */ if (sctp->sctp_state >= SCTPS_ESTABLISHED && !sctp->sctp_loopback) { skip_lback = B_TRUE; } for (i = 0; i < SCTP_IPIF_HASH; i++) { if (sctp->sctp_saddrs[i].ipif_count == 0) continue; pobj = list_object(&sctp->sctp_saddrs[i].sctp_ipif_list, sctp->sctp_saddrs[i].sctp_ipif_list.list_head.list_next); if (mdb_vread(&obj, sizeof (sctp_saddr_ipif_t), (uintptr_t)pobj) == -1) { mdb_warn("failed to read sctp_saddr_ipif_t"); return (err); } for (l = 0; l < sctp->sctp_saddrs[i].ipif_count; l++) { sctp_ipif_t ipif; in6_addr_t laddr; list_node_t *pnode; list_node_t node; if (mdb_vread(&ipif, sizeof (sctp_ipif_t), (uintptr_t)obj.saddr_ipifp) == -1) { mdb_warn("failed to read sctp_ipif_t"); return (err); } laddr = ipif.sctp_ipif_saddr; scanned++; if ((ipif.sctp_ipif_state == SCTP_IPIFS_CONDEMNED) || SCTP_DONT_SRC(&obj) || (ipif.sctp_ipif_ill->sctp_ill_flags & PHYI_LOOPBACK) && skip_lback) { if (scanned >= sctp->sctp_nsaddrs) goto done; /* LINTED: alignment */ pnode = list_d2l(&sctp->sctp_saddrs[i]. sctp_ipif_list, pobj); if (mdb_vread(&node, sizeof (list_node_t), (uintptr_t)pnode) == -1) { mdb_warn("failed to read list_node_t"); return (err); } pobj = list_object(&sctp->sctp_saddrs[i]. sctp_ipif_list, node.list_next); if (mdb_vread(&obj, sizeof (sctp_saddr_ipif_t), (uintptr_t)pobj) == -1) { mdb_warn("failed to read " "sctp_saddr_ipif_t"); return (err); } continue; } switch (connp->conn_family) { case AF_INET: /* LINTED: alignment */ sin4 = (sin_t *)addr; if ((sctp->sctp_state <= SCTPS_LISTEN) && sctp->sctp_bound_to_all) { sin4->sin_addr.s_addr = INADDR_ANY; sin4->sin_port = connp->conn_lport; } else { sin4 += added; sin4->sin_family = AF_INET; sin4->sin_port = connp->conn_lport; IN6_V4MAPPED_TO_INADDR(&laddr, &sin4->sin_addr); } break; case AF_INET6: /* LINTED: alignment */ sin6 = (sin6_t *)addr; if ((sctp->sctp_state <= SCTPS_LISTEN) && sctp->sctp_bound_to_all) { bzero(&sin6->sin6_addr, sizeof (sin6->sin6_addr)); sin6->sin6_port = connp->conn_lport; } else { sin6 += added; sin6->sin6_family = AF_INET6; sin6->sin6_port = connp->conn_lport; sin6->sin6_addr = laddr; } sin6->sin6_flowinfo = connp->conn_flowinfo; sin6->sin6_scope_id = 0; sin6->__sin6_src_id = 0; break; } added++; if (added >= 1) { err = 0; goto done; } if (scanned >= sctp->sctp_nsaddrs) goto done; /* LINTED: alignment */ pnode = list_d2l(&sctp->sctp_saddrs[i].sctp_ipif_list, pobj); if (mdb_vread(&node, sizeof (list_node_t), (uintptr_t)pnode) == -1) { mdb_warn("failed to read list_node_t"); return (err); } pobj = list_object(&sctp->sctp_saddrs[i]. sctp_ipif_list, node.list_next); if (mdb_vread(&obj, sizeof (sctp_saddr_ipif_t), (uintptr_t)pobj) == -1) { mdb_warn("failed to read sctp_saddr_ipif_t"); return (err); } } } done: return (err); } /* * SCTP interface for geting the primary peer address of a sctp_t. */ static int sctp_getpeeraddr(sctp_t *sctp, struct sockaddr *addr) { struct sockaddr_in *sin4; struct sockaddr_in6 *sin6; sctp_faddr_t sctp_primary; in6_addr_t faddr; conn_t *connp = sctp->sctp_connp; if (sctp->sctp_faddrs == NULL) return (-1); addr->sa_family = connp->conn_family; if (mdb_vread(&sctp_primary, sizeof (sctp_faddr_t), (uintptr_t)sctp->sctp_primary) == -1) { mdb_warn("failed to read sctp primary faddr"); return (-1); } faddr = sctp_primary.faddr; switch (connp->conn_family) { case AF_INET: /* LINTED: alignment */ sin4 = (struct sockaddr_in *)addr; IN6_V4MAPPED_TO_INADDR(&faddr, &sin4->sin_addr); sin4->sin_port = connp->conn_fport; sin4->sin_family = AF_INET; break; case AF_INET6: /* LINTED: alignment */ sin6 = (struct sockaddr_in6 *)addr; sin6->sin6_addr = faddr; sin6->sin6_port = connp->conn_fport; sin6->sin6_family = AF_INET6; sin6->sin6_flowinfo = 0; sin6->sin6_scope_id = 0; sin6->__sin6_src_id = 0; break; } return (0); } static int tpi_sock_print(sotpi_sonode_t *sotpi_sonode) { if (sotpi_sonode->st_info.sti_laddr_valid == 1) { struct sockaddr *laddr = mdb_alloc(sotpi_sonode->st_info.sti_laddr_len, UM_SLEEP); if (mdb_vread(laddr, sotpi_sonode->st_info.sti_laddr_len, (uintptr_t)sotpi_sonode->st_info.sti_laddr_sa) == -1) { mdb_warn("failed to read sotpi_sonode socket addr"); return (-1); } mdb_printf("socket: "); pfiles_print_addr(laddr); } if (sotpi_sonode->st_info.sti_faddr_valid == 1) { struct sockaddr *faddr = mdb_alloc(sotpi_sonode->st_info.sti_faddr_len, UM_SLEEP); if (mdb_vread(faddr, sotpi_sonode->st_info.sti_faddr_len, (uintptr_t)sotpi_sonode->st_info.sti_faddr_sa) == -1) { mdb_warn("failed to read sotpi_sonode remote addr"); return (-1); } mdb_printf("remote: "); pfiles_print_addr(faddr); } return (0); } static int tcpip_sock_print(struct sonode *socknode) { switch (socknode->so_family) { case AF_INET: { conn_t conn_t; in_port_t port; if (mdb_vread(&conn_t, sizeof (conn_t), (uintptr_t)socknode->so_proto_handle) == -1) { mdb_warn("failed to read conn_t V4"); return (-1); } mdb_printf("socket: "); mdb_nhconvert(&port, &conn_t.conn_lport, sizeof (port)); mdb_printf("AF_INET %I %d ", conn_t.conn_laddr_v4, port); /* * If this is a listening socket, we don't print * the remote address. */ if (IPCL_IS_TCP(&conn_t) && IPCL_IS_BOUND(&conn_t) == 0 || IPCL_IS_UDP(&conn_t) && IPCL_IS_CONNECTED(&conn_t)) { mdb_printf("remote: "); mdb_nhconvert(&port, &conn_t.conn_fport, sizeof (port)); mdb_printf("AF_INET %I %d ", conn_t.conn_faddr_v4, port); } break; } case AF_INET6: { conn_t conn_t; in_port_t port; if (mdb_vread(&conn_t, sizeof (conn_t), (uintptr_t)socknode->so_proto_handle) == -1) { mdb_warn("failed to read conn_t V6"); return (-1); } mdb_printf("socket: "); mdb_nhconvert(&port, &conn_t.conn_lport, sizeof (port)); mdb_printf("AF_INET6 %N %d ", &conn_t.conn_laddr_v4, port); /* * If this is a listening socket, we don't print * the remote address. */ if (IPCL_IS_TCP(&conn_t) && IPCL_IS_BOUND(&conn_t) == 0 || IPCL_IS_UDP(&conn_t) && IPCL_IS_CONNECTED(&conn_t)) { mdb_printf("remote: "); mdb_nhconvert(&port, &conn_t.conn_fport, sizeof (port)); mdb_printf("AF_INET6 %N %d ", &conn_t.conn_faddr_v6, port); } break; } default: mdb_printf("AF_?? (%d)", socknode->so_family); break; } return (0); } static int sctp_sock_print(struct sonode *socknode) { sctp_t sctp_t; conn_t conns; struct sockaddr *laddr = mdb_alloc(sizeof (struct sockaddr), UM_SLEEP); struct sockaddr *faddr = mdb_alloc(sizeof (struct sockaddr), UM_SLEEP); if (mdb_vread(&sctp_t, sizeof (sctp_t), (uintptr_t)socknode->so_proto_handle) == -1) { mdb_warn("failed to read sctp_t"); return (-1); } if (mdb_vread(&conns, sizeof (conn_t), (uintptr_t)sctp_t.sctp_connp) == -1) { mdb_warn("failed to read conn_t at %p", (uintptr_t)sctp_t.sctp_connp); return (-1); } sctp_t.sctp_connp = &conns; if (sctp_getsockaddr(&sctp_t, laddr) == 0) { mdb_printf("socket:"); pfiles_print_addr(laddr); } if (sctp_getpeeraddr(&sctp_t, faddr) == 0) { mdb_printf("remote:"); pfiles_print_addr(faddr); } return (0); } /* ARGSUSED */ static int sdp_sock_print(struct sonode *socknode) { return (0); } struct sock_print { int family; int type; int pro; int (*print)(struct sonode *socknode); } sock_prints[] = { { 2, 2, 0, tcpip_sock_print }, /* /dev/tcp */ { 2, 2, 6, tcpip_sock_print }, /* /dev/tcp */ { 26, 2, 0, tcpip_sock_print }, /* /dev/tcp6 */ { 26, 2, 6, tcpip_sock_print }, /* /dev/tcp6 */ { 2, 1, 0, tcpip_sock_print }, /* /dev/udp */ { 2, 1, 17, tcpip_sock_print }, /* /dev/udp */ { 26, 1, 0, tcpip_sock_print }, /* /dev/udp6 */ { 26, 1, 17, tcpip_sock_print }, /* /dev/udp6 */ { 2, 4, 0, tcpip_sock_print }, /* /dev/rawip */ { 26, 4, 0, tcpip_sock_print }, /* /dev/rawip6 */ { 2, 2, 132, sctp_sock_print }, /* /dev/sctp */ { 26, 2, 132, sctp_sock_print }, /* /dev/sctp6 */ { 2, 6, 132, sctp_sock_print }, /* /dev/sctp */ { 26, 6, 132, sctp_sock_print }, /* /dev/sctp6 */ { 24, 4, 0, tcpip_sock_print }, /* /dev/rts */ { 2, 2, 257, sdp_sock_print }, /* /dev/sdp */ { 26, 2, 257, sdp_sock_print }, /* /dev/sdp */ }; #define NUM_SOCK_PRINTS \ (sizeof (sock_prints) / sizeof (struct sock_print)) static int pfile_callback(uintptr_t addr, const struct file *f, struct pfiles_cbdata *cb) { vnode_t v, layer_vn; int myfd = cb->fd; const char *type; char path[MAXPATHLEN]; uintptr_t top_vnodep, realvpp; char fsname[_ST_FSTYPSZ]; int err, i; cb->fd++; if (addr == NULL) { return (WALK_NEXT); } top_vnodep = realvpp = (uintptr_t)f->f_vnode; if (mdb_vread(&v, sizeof (v), realvpp) == -1) { mdb_warn("failed to read vnode"); return (DCMD_ERR); } type = "?"; for (i = 0; i <= NUM_FS_TYPES; i++) { if (fs_types[i].type == v.v_type) type = fs_types[i].name; } do { uintptr_t next_realvpp; err = next_realvp(realvpp, &layer_vn, &next_realvpp); if (next_realvpp != NULL) realvpp = next_realvpp; } while (err == REALVP_CONTINUE); if (err == REALVP_ERR) { mdb_warn("failed to do realvp() for %p", realvpp); return (DCMD_ERR); } if (read_fsname((uintptr_t)layer_vn.v_vfsp, fsname) == -1) return (DCMD_ERR); mdb_printf("%4d %4s %?0p ", myfd, type, top_vnodep); if (cb->opt_p) { if (pfiles_dig_pathname(top_vnodep, path) == -1) return (DCMD_ERR); mdb_printf("%s\n", path); return (DCMD_OK); } /* * Sockets generally don't have interesting pathnames; we only * show those in the '-p' view. */ path[0] = '\0'; if (v.v_type != VSOCK) { if (pfiles_dig_pathname(top_vnodep, path) == -1) return (DCMD_ERR); } mdb_printf("%s%s", path, path[0] == '\0' ? "" : " "); switch (v.v_type) { case VDOOR: { door_node_t doornode; proc_t pr; if (mdb_vread(&doornode, sizeof (doornode), (uintptr_t)layer_vn.v_data) == -1) { mdb_warn("failed to read door_node"); return (DCMD_ERR); } if (mdb_vread(&pr, sizeof (pr), (uintptr_t)doornode.door_target) == -1) { mdb_warn("failed to read door server process %p", doornode.door_target); return (DCMD_ERR); } mdb_printf("[door to '%s' (proc=%p)]", pr.p_user.u_comm, doornode.door_target); break; } case VSOCK: { vnode_t v_sock; struct sonode so; if (mdb_vread(&v_sock, sizeof (v_sock), realvpp) == -1) { mdb_warn("failed to read socket vnode"); return (DCMD_ERR); } /* * Sockets can be non-stream or stream, they have to be dealed * with differently. */ if (v_sock.v_stream == NULL) { if (pfiles_get_sonode(&v_sock, &so) == -1) return (DCMD_ERR); /* Pick the proper methods. */ for (i = 0; i <= NUM_SOCK_PRINTS; i++) { if ((sock_prints[i].family == so.so_family && sock_prints[i].type == so.so_type && sock_prints[i].pro == so.so_protocol) || (sock_prints[i].family == so.so_family && sock_prints[i].type == so.so_type && so.so_type == SOCK_RAW)) { if ((*sock_prints[i].print)(&so) == -1) return (DCMD_ERR); } } } else { sotpi_sonode_t sotpi_sonode; if (pfiles_get_sonode(&v_sock, &so) == -1) return (DCMD_ERR); /* * If the socket is a fallback socket, read its related * information separately; otherwise, read it as a whole * tpi socket. */ if (so.so_state & SS_FALLBACK_COMP) { sotpi_sonode.st_sonode = so; if (mdb_vread(&(sotpi_sonode.st_info), sizeof (sotpi_info_t), (uintptr_t)so.so_priv) == -1) return (DCMD_ERR); } else { if (pfiles_get_tpi_sonode(&v_sock, &sotpi_sonode) == -1) return (DCMD_ERR); } if (tpi_sock_print(&sotpi_sonode) == -1) return (DCMD_ERR); } break; } case VPORT: mdb_printf("[event port (port=%p)]", v.v_data); break; case VPROC: { prnode_t prnode; prcommon_t prcommon; if (mdb_vread(&prnode, sizeof (prnode), (uintptr_t)layer_vn.v_data) == -1) { mdb_warn("failed to read prnode"); return (DCMD_ERR); } if (mdb_vread(&prcommon, sizeof (prcommon), (uintptr_t)prnode.pr_common) == -1) { mdb_warn("failed to read prcommon %p", prnode.pr_common); return (DCMD_ERR); } mdb_printf("(proc=%p)", prcommon.prc_proc); break; } default: break; } mdb_printf("\n"); return (WALK_NEXT); } static int file_t_callback(uintptr_t addr, const struct file *f, struct pfiles_cbdata *cb) { int myfd = cb->fd; cb->fd++; if (addr == NULL) { return (WALK_NEXT); } /* * We really need 20 digits to print a 64-bit offset_t, but this * is exceedingly rare, so we cheat and assume a column width of 10 * digits, in order to fit everything cleanly into 80 columns. */ mdb_printf("%?0p %4d %8x %?0p %10lld %?0p %4d\n", addr, myfd, f->f_flag, f->f_vnode, f->f_offset, f->f_cred, f->f_count); return (WALK_NEXT); } int pfiles(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { int opt_f = 0; struct pfiles_cbdata cb; bzero(&cb, sizeof (cb)); if (!(flags & DCMD_ADDRSPEC)) return (DCMD_USAGE); if (mdb_getopts(argc, argv, 'p', MDB_OPT_SETBITS, TRUE, &cb.opt_p, 'f', MDB_OPT_SETBITS, TRUE, &opt_f, NULL) != argc) return (DCMD_USAGE); if (opt_f) { mdb_printf("%%?s %4s %8s %?s %10s %?s %4s%\n", "FILE", "FD", "FLAG", "VNODE", "OFFSET", "CRED", "CNT"); if (mdb_pwalk("allfile", (mdb_walk_cb_t)file_t_callback, &cb, addr) == -1) { mdb_warn("failed to walk 'allfile'"); return (DCMD_ERR); } } else { mdb_printf("%%-4s %4s %?s ", "FD", "TYPE", "VNODE"); if (cb.opt_p) mdb_printf("PATH"); else mdb_printf("INFO"); mdb_printf("%\n"); if (mdb_pwalk("allfile", (mdb_walk_cb_t)pfile_callback, &cb, addr) == -1) { mdb_warn("failed to walk 'allfile'"); return (DCMD_ERR); } } return (DCMD_OK); } void pfiles_help(void) { mdb_printf( "Given the address of a process, print information about files\n" "which the process has open. By default, this includes decoded\n" "information about the file depending on file and filesystem type\n" "\n" "\t-p\tPathnames; omit decoded information. Only display " "pathnames\n" "\t-f\tfile_t view; show the file_t structure corresponding to " "the fd\n"); }