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/*- * Copyright (c) 1999-2002, 2006, 2009 Robert N. M. Watson * Copyright (c) 2001 Ilmar S. Habibulin * Copyright (c) 2001-2005 Networks Associates Technology, Inc. * Copyright (c) 2005-2006 SPARTA, Inc. * Copyright (c) 2008-2009 Apple Inc. * All rights reserved. * * This software was developed by Robert Watson and Ilmar Habibulin for the * TrustedBSD Project. * * This software was developed for the FreeBSD Project in part by Network * Associates Laboratories, the Security Research Division of Network * Associates, Inc. under DARPA/SPAWAR contract N66001-01-C-8035 ("CBOSS"), * as part of the DARPA CHATS research program. * * This software was enhanced by SPARTA ISSO under SPAWAR contract * N66001-04-C-6019 ("SEFOS"). * * This software was developed at the University of Cambridge Computer * Laboratory with support from a grant from Google, Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /*- * Framework for extensible kernel access control. This file contains core * kernel infrastructure for the TrustedBSD MAC Framework, including policy * registration, versioning, locking, error composition operator, and system * calls. * * The MAC Framework implements three programming interfaces: * * - The kernel MAC interface, defined in mac_framework.h, and invoked * throughout the kernel to request security decisions, notify of security * related events, etc. * * - The MAC policy module interface, defined in mac_policy.h, which is * implemented by MAC policy modules and invoked by the MAC Framework to * forward kernel security requests and notifications to policy modules. * * - The user MAC API, defined in mac.h, which allows user programs to query * and set label state on objects. * * The majority of the MAC Framework implementation may be found in * src/sys/security/mac. Sample policy modules may be found in * src/sys/security/mac_*. */ #include "opt_kdtrace.h" #include "opt_mac.h" #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/security/mac/mac_framework.c 230167 2012-01-15 21:58:51Z avg $"); #include <sys/param.h> #include <sys/systm.h> #include <sys/condvar.h> #include <sys/kernel.h> #include <sys/lock.h> #include <sys/mac.h> #include <sys/module.h> #include <sys/rmlock.h> #include <sys/sdt.h> #include <sys/sx.h> #include <sys/sysctl.h> #include <security/mac/mac_framework.h> #include <security/mac/mac_internal.h> #include <security/mac/mac_policy.h> /* * DTrace SDT providers for MAC. */ SDT_PROVIDER_DEFINE(mac); SDT_PROVIDER_DEFINE(mac_framework); SDT_PROBE_DEFINE2(mac, kernel, policy, modevent, modevent, "int", "struct mac_policy_conf *mpc"); SDT_PROBE_DEFINE1(mac, kernel, policy, register, register, "struct mac_policy_conf *"); SDT_PROBE_DEFINE1(mac, kernel, policy, unregister, unregister, "struct mac_policy_conf *"); /* * Root sysctl node for all MAC and MAC policy controls. */ SYSCTL_NODE(_security, OID_AUTO, mac, CTLFLAG_RW, 0, "TrustedBSD MAC policy controls"); /* * Declare that the kernel provides MAC support, version 3 (FreeBSD 7.x). * This permits modules to refuse to be loaded if the necessary support isn't * present, even if it's pre-boot. */ MODULE_VERSION(kernel_mac_support, MAC_VERSION); static unsigned int mac_version = MAC_VERSION; SYSCTL_UINT(_security_mac, OID_AUTO, version, CTLFLAG_RD, &mac_version, 0, ""); /* * Labels consist of a indexed set of "slots", which are allocated policies * as required. The MAC Framework maintains a bitmask of slots allocated so * far to prevent reuse. Slots cannot be reused, as the MAC Framework * guarantees that newly allocated slots in labels will be NULL unless * otherwise initialized, and because we do not have a mechanism to garbage * collect slots on policy unload. As labeled policies tend to be statically * loaded during boot, and not frequently unloaded and reloaded, this is not * generally an issue. */ #if MAC_MAX_SLOTS > 32 #error "MAC_MAX_SLOTS too large" #endif static unsigned int mac_max_slots = MAC_MAX_SLOTS; static unsigned int mac_slot_offsets_free = (1 << MAC_MAX_SLOTS) - 1; SYSCTL_UINT(_security_mac, OID_AUTO, max_slots, CTLFLAG_RD, &mac_max_slots, 0, ""); /* * Has the kernel started generating labeled objects yet? All read/write * access to this variable is serialized during the boot process. Following * the end of serialization, we don't update this flag; no locking. */ static int mac_late = 0; /* * Each policy declares a mask of object types requiring labels to be * allocated for them. For convenience, we combine and cache the bitwise or * of the per-policy object flags to track whether we will allocate a label * for an object type at run-time. */ uint64_t mac_labeled; SYSCTL_UQUAD(_security_mac, OID_AUTO, labeled, CTLFLAG_RD, &mac_labeled, 0, "Mask of object types being labeled"); MALLOC_DEFINE(M_MACTEMP, "mactemp", "MAC temporary label storage"); /* * MAC policy modules are placed in one of two lists: mac_static_policy_list, * for policies that are loaded early and cannot be unloaded, and * mac_policy_list, which holds policies either loaded later in the boot * cycle or that may be unloaded. The static policy list does not require * locks to iterate over, but the dynamic list requires synchronization. * Support for dynamic policy loading can be compiled out using the * MAC_STATIC kernel option. * * The dynamic policy list is protected by two locks: modifying the list * requires both locks to be held exclusively. One of the locks, * mac_policy_rm, is acquired over policy entry points that will never sleep; * the other, mac_policy_sx, is acquire over policy entry points that may * sleep. The former category will be used when kernel locks may be held * over calls to the MAC Framework, during network processing in ithreads, * etc. The latter will tend to involve potentially blocking memory * allocations, extended attribute I/O, etc. */ #ifndef MAC_STATIC static struct rmlock mac_policy_rm; /* Non-sleeping entry points. */ static struct sx mac_policy_sx; /* Sleeping entry points. */ #endif struct mac_policy_list_head mac_policy_list; struct mac_policy_list_head mac_static_policy_list; u_int mac_policy_count; /* Registered policy count. */ static void mac_policy_xlock(void); static void mac_policy_xlock_assert(void); static void mac_policy_xunlock(void); void mac_policy_slock_nosleep(struct rm_priotracker *tracker) { #ifndef MAC_STATIC if (!mac_late) return; rm_rlock(&mac_policy_rm, tracker); #endif } void mac_policy_slock_sleep(void) { WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, "mac_policy_slock_sleep"); #ifndef MAC_STATIC if (!mac_late) return; sx_slock(&mac_policy_sx); #endif } void mac_policy_sunlock_nosleep(struct rm_priotracker *tracker) { #ifndef MAC_STATIC if (!mac_late) return; rm_runlock(&mac_policy_rm, tracker); #endif } void mac_policy_sunlock_sleep(void) { #ifndef MAC_STATIC if (!mac_late) return; sx_sunlock(&mac_policy_sx); #endif } static void mac_policy_xlock(void) { WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, "mac_policy_xlock()"); #ifndef MAC_STATIC if (!mac_late) return; sx_xlock(&mac_policy_sx); rm_wlock(&mac_policy_rm); #endif } static void mac_policy_xunlock(void) { #ifndef MAC_STATIC if (!mac_late) return; rm_wunlock(&mac_policy_rm); sx_xunlock(&mac_policy_sx); #endif } static void mac_policy_xlock_assert(void) { #ifndef MAC_STATIC if (!mac_late) return; /* XXXRW: rm_assert(&mac_policy_rm, RA_WLOCKED); */ sx_assert(&mac_policy_sx, SA_XLOCKED); #endif } /* * Initialize the MAC subsystem, including appropriate SMP locks. */ static void mac_init(void) { LIST_INIT(&mac_static_policy_list); LIST_INIT(&mac_policy_list); mac_labelzone_init(); #ifndef MAC_STATIC rm_init_flags(&mac_policy_rm, "mac_policy_rm", RM_NOWITNESS); sx_init_flags(&mac_policy_sx, "mac_policy_sx", SX_NOWITNESS); #endif } /* * For the purposes of modules that want to know if they were loaded "early", * set the mac_late flag once we've processed modules either linked into the * kernel, or loaded before the kernel startup. */ static void mac_late_init(void) { mac_late = 1; } /* * Given a policy, derive from its set of non-NULL label init methods what * object types the policy is interested in. */ static uint64_t mac_policy_getlabeled(struct mac_policy_conf *mpc) { uint64_t labeled; #define MPC_FLAG(method, flag) \ if (mpc->mpc_ops->mpo_ ## method != NULL) \ labeled |= (flag); \ labeled = 0; MPC_FLAG(cred_init_label, MPC_OBJECT_CRED); MPC_FLAG(proc_init_label, MPC_OBJECT_PROC); MPC_FLAG(vnode_init_label, MPC_OBJECT_VNODE); MPC_FLAG(inpcb_init_label, MPC_OBJECT_INPCB); MPC_FLAG(socket_init_label, MPC_OBJECT_SOCKET); MPC_FLAG(devfs_init_label, MPC_OBJECT_DEVFS); MPC_FLAG(mbuf_init_label, MPC_OBJECT_MBUF); MPC_FLAG(ipq_init_label, MPC_OBJECT_IPQ); MPC_FLAG(ifnet_init_label, MPC_OBJECT_IFNET); MPC_FLAG(bpfdesc_init_label, MPC_OBJECT_BPFDESC); MPC_FLAG(pipe_init_label, MPC_OBJECT_PIPE); MPC_FLAG(mount_init_label, MPC_OBJECT_MOUNT); MPC_FLAG(posixsem_init_label, MPC_OBJECT_POSIXSEM); MPC_FLAG(posixshm_init_label, MPC_OBJECT_POSIXSHM); MPC_FLAG(sysvmsg_init_label, MPC_OBJECT_SYSVMSG); MPC_FLAG(sysvmsq_init_label, MPC_OBJECT_SYSVMSQ); MPC_FLAG(sysvsem_init_label, MPC_OBJECT_SYSVSEM); MPC_FLAG(sysvshm_init_label, MPC_OBJECT_SYSVSHM); MPC_FLAG(syncache_init_label, MPC_OBJECT_SYNCACHE); MPC_FLAG(ip6q_init_label, MPC_OBJECT_IP6Q); #undef MPC_FLAG return (labeled); } /* * When policies are loaded or unloaded, walk the list of registered policies * and built mac_labeled, a bitmask representing the union of all objects * requiring labels across all policies. */ static void mac_policy_update(void) { struct mac_policy_conf *mpc; mac_policy_xlock_assert(); mac_labeled = 0; mac_policy_count = 0; LIST_FOREACH(mpc, &mac_static_policy_list, mpc_list) { mac_labeled |= mac_policy_getlabeled(mpc); mac_policy_count++; } LIST_FOREACH(mpc, &mac_policy_list, mpc_list) { mac_labeled |= mac_policy_getlabeled(mpc); mac_policy_count++; } } static int mac_policy_register(struct mac_policy_conf *mpc) { struct mac_policy_conf *tmpc; int error, slot, static_entry; error = 0; /* * We don't technically need exclusive access while !mac_late, but * hold it for assertion consistency. */ mac_policy_xlock(); /* * If the module can potentially be unloaded, or we're loading late, * we have to stick it in the non-static list and pay an extra * performance overhead. Otherwise, we can pay a light locking cost * and stick it in the static list. */ static_entry = (!mac_late && !(mpc->mpc_loadtime_flags & MPC_LOADTIME_FLAG_UNLOADOK)); if (static_entry) { LIST_FOREACH(tmpc, &mac_static_policy_list, mpc_list) { if (strcmp(tmpc->mpc_name, mpc->mpc_name) == 0) { error = EEXIST; goto out; } } } else { LIST_FOREACH(tmpc, &mac_policy_list, mpc_list) { if (strcmp(tmpc->mpc_name, mpc->mpc_name) == 0) { error = EEXIST; goto out; } } } if (mpc->mpc_field_off != NULL) { slot = ffs(mac_slot_offsets_free); if (slot == 0) { error = ENOMEM; goto out; } slot--; mac_slot_offsets_free &= ~(1 << slot); *mpc->mpc_field_off = slot; } mpc->mpc_runtime_flags |= MPC_RUNTIME_FLAG_REGISTERED; /* * If we're loading a MAC module after the framework has initialized, * it has to go into the dynamic list. If we're loading it before * we've finished initializing, it can go into the static list with * weaker locker requirements. */ if (static_entry) LIST_INSERT_HEAD(&mac_static_policy_list, mpc, mpc_list); else LIST_INSERT_HEAD(&mac_policy_list, mpc, mpc_list); /* * Per-policy initialization. Currently, this takes place under the * exclusive lock, so policies must not sleep in their init method. * In the future, we may want to separate "init" from "start", with * "init" occuring without the lock held. Likewise, on tear-down, * breaking out "stop" from "destroy". */ if (mpc->mpc_ops->mpo_init != NULL) (*(mpc->mpc_ops->mpo_init))(mpc); mac_policy_update(); SDT_PROBE(mac, kernel, policy, register, mpc, 0, 0, 0, 0); printf("Security policy loaded: %s (%s)\n", mpc->mpc_fullname, mpc->mpc_name); out: mac_policy_xunlock(); return (error); } static int mac_policy_unregister(struct mac_policy_conf *mpc) { /* * If we fail the load, we may get a request to unload. Check to see * if we did the run-time registration, and if not, silently succeed. */ mac_policy_xlock(); if ((mpc->mpc_runtime_flags & MPC_RUNTIME_FLAG_REGISTERED) == 0) { mac_policy_xunlock(); return (0); } #if 0 /* * Don't allow unloading modules with private data. */ if (mpc->mpc_field_off != NULL) { mac_policy_xunlock(); return (EBUSY); } #endif /* * Only allow the unload to proceed if the module is unloadable by * its own definition. */ if ((mpc->mpc_loadtime_flags & MPC_LOADTIME_FLAG_UNLOADOK) == 0) { mac_policy_xunlock(); return (EBUSY); } if (mpc->mpc_ops->mpo_destroy != NULL) (*(mpc->mpc_ops->mpo_destroy))(mpc); LIST_REMOVE(mpc, mpc_list); mpc->mpc_runtime_flags &= ~MPC_RUNTIME_FLAG_REGISTERED; mac_policy_update(); mac_policy_xunlock(); SDT_PROBE(mac, kernel, policy, unregister, mpc, 0, 0, 0, 0); printf("Security policy unload: %s (%s)\n", mpc->mpc_fullname, mpc->mpc_name); return (0); } /* * Allow MAC policy modules to register during boot, etc. */ int mac_policy_modevent(module_t mod, int type, void *data) { struct mac_policy_conf *mpc; int error; error = 0; mpc = (struct mac_policy_conf *) data; #ifdef MAC_STATIC if (mac_late) { printf("mac_policy_modevent: MAC_STATIC and late\n"); return (EBUSY); } #endif SDT_PROBE(mac, kernel, policy, modevent, type, mpc, 0, 0, 0); switch (type) { case MOD_LOAD: if (mpc->mpc_loadtime_flags & MPC_LOADTIME_FLAG_NOTLATE && mac_late) { printf("mac_policy_modevent: can't load %s policy " "after booting\n", mpc->mpc_name); error = EBUSY; break; } error = mac_policy_register(mpc); break; case MOD_UNLOAD: /* Don't unregister the module if it was never registered. */ if ((mpc->mpc_runtime_flags & MPC_RUNTIME_FLAG_REGISTERED) != 0) error = mac_policy_unregister(mpc); else error = 0; break; default: error = EOPNOTSUPP; break; } return (error); } /* * Define an error value precedence, and given two arguments, selects the * value with the higher precedence. */ int mac_error_select(int error1, int error2) { /* Certain decision-making errors take top priority. */ if (error1 == EDEADLK || error2 == EDEADLK) return (EDEADLK); /* Invalid arguments should be reported where possible. */ if (error1 == EINVAL || error2 == EINVAL) return (EINVAL); /* Precedence goes to "visibility", with both process and file. */ if (error1 == ESRCH || error2 == ESRCH) return (ESRCH); if (error1 == ENOENT || error2 == ENOENT) return (ENOENT); /* Precedence goes to DAC/MAC protections. */ if (error1 == EACCES || error2 == EACCES) return (EACCES); /* Precedence goes to privilege. */ if (error1 == EPERM || error2 == EPERM) return (EPERM); /* Precedence goes to error over success; otherwise, arbitrary. */ if (error1 != 0) return (error1); return (error2); } int mac_check_structmac_consistent(struct mac *mac) { if (mac->m_buflen < 0 || mac->m_buflen > MAC_MAX_LABEL_BUF_LEN) return (EINVAL); return (0); } SYSINIT(mac, SI_SUB_MAC, SI_ORDER_FIRST, mac_init, NULL); SYSINIT(mac_late, SI_SUB_MAC_LATE, SI_ORDER_FIRST, mac_late_init, NULL);