freebsd-dev/sys/security/audit/audit_private.h

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/*-
* Copyright (c) 1999-2009 Apple Inc.
* All rights reserved.
*
* 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. Neither the name of Apple Inc. ("Apple") 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 APPLE AND ITS 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 APPLE OR ITS 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.
*
* $FreeBSD$
*/
/*
* This include file contains function prototypes and type definitions used
* within the audit implementation.
*/
#ifndef _SECURITY_AUDIT_PRIVATE_H_
#define _SECURITY_AUDIT_PRIVATE_H_
#ifndef _KERNEL
#error "no user-serviceable parts inside"
#endif
#include <sys/ipc.h>
#include <sys/socket.h>
#include <sys/ucred.h>
#ifdef MALLOC_DECLARE
MALLOC_DECLARE(M_AUDITBSM);
MALLOC_DECLARE(M_AUDITDATA);
MALLOC_DECLARE(M_AUDITPATH);
MALLOC_DECLARE(M_AUDITTEXT);
MALLOC_DECLARE(M_AUDITGIDSET);
#endif
/*
* Audit control variables that are usually set/read via system calls and
* used to control various aspects of auditing.
*/
extern struct au_qctrl audit_qctrl;
extern struct audit_fstat audit_fstat;
extern struct au_mask audit_nae_mask;
extern int audit_panic_on_write_fail;
extern int audit_fail_stop;
extern int audit_argv;
extern int audit_arge;
/*
* Success/failure conditions for the conversion of a kernel audit record to
* BSM format.
*/
#define BSM_SUCCESS 0
#define BSM_FAILURE 1
#define BSM_NOAUDIT 2
/*
Introduce support for per-audit pipe preselection independent from the global audit trail configuration. This allows applications consuming audit trails to specify parameters for which audit records are of interest, including selecting records not required by the global trail. Allowing application interest specification without changing the global configuration allows intrusion detection systems to run without interfering with global auditing or each other (if multiple are present). To implement this: - Kernel audit records now carry a flag to indicate whether they have been selected by the global trail or by the audit pipe subsystem, set during record commit, so that this information is available after BSM conversion when delivering the BSM to the trail and audit pipes in the audit worker thread asynchronously. Preselection by either record target will cause the record to be kept. - Similar changes to preselection when the audit record is created when the system call is entering: consult both the global trail and pipes. - au_preselect() now accepts the class in order to avoid repeatedly looking up the mask for each preselection test. - Define a series of ioctls that allow applications to specify whether they want to track the global trail, or program their own preselection parameters: they may specify their own flags and naflags masks, similar to the global masks of the same name, as well as a set of per-auid masks. They also set a per-pipe mode specifying whether they track the global trail, or user their own -- the door is left open for future additional modes. A new ioctl is defined to allow a user process to flush the current audit pipe queue, which can be used after reprogramming pre-selection to make sure that only records of interest are received in future reads. - Audit pipe data structures are extended to hold the additional fields necessary to support preselection. By default, audit pipes track the global trail, so "praudit /dev/auditpipe" will track the global audit trail even though praudit doesn't program the audit pipe selection model. - Comment about the complexities of potentially adding partial read support to audit pipes. By using a set of ioctls, applications can select which records are of interest, and toggle the preselection mode. Obtained from: TrustedBSD Project
2006-06-05 14:48:17 +00:00
* Defines for the kernel audit record k_ar_commit field. Flags are set to
* indicate what sort of record it is, and which preselection mechanism
* selected it.
*/
#define AR_COMMIT_KERNEL 0x00000001U
#define AR_COMMIT_USER 0x00000010U
Introduce support for per-audit pipe preselection independent from the global audit trail configuration. This allows applications consuming audit trails to specify parameters for which audit records are of interest, including selecting records not required by the global trail. Allowing application interest specification without changing the global configuration allows intrusion detection systems to run without interfering with global auditing or each other (if multiple are present). To implement this: - Kernel audit records now carry a flag to indicate whether they have been selected by the global trail or by the audit pipe subsystem, set during record commit, so that this information is available after BSM conversion when delivering the BSM to the trail and audit pipes in the audit worker thread asynchronously. Preselection by either record target will cause the record to be kept. - Similar changes to preselection when the audit record is created when the system call is entering: consult both the global trail and pipes. - au_preselect() now accepts the class in order to avoid repeatedly looking up the mask for each preselection test. - Define a series of ioctls that allow applications to specify whether they want to track the global trail, or program their own preselection parameters: they may specify their own flags and naflags masks, similar to the global masks of the same name, as well as a set of per-auid masks. They also set a per-pipe mode specifying whether they track the global trail, or user their own -- the door is left open for future additional modes. A new ioctl is defined to allow a user process to flush the current audit pipe queue, which can be used after reprogramming pre-selection to make sure that only records of interest are received in future reads. - Audit pipe data structures are extended to hold the additional fields necessary to support preselection. By default, audit pipes track the global trail, so "praudit /dev/auditpipe" will track the global audit trail even though praudit doesn't program the audit pipe selection model. - Comment about the complexities of potentially adding partial read support to audit pipes. By using a set of ioctls, applications can select which records are of interest, and toggle the preselection mode. Obtained from: TrustedBSD Project
2006-06-05 14:48:17 +00:00
#define AR_PRESELECT_TRAIL 0x00001000U
#define AR_PRESELECT_PIPE 0x00002000U
#define AR_PRESELECT_USER_TRAIL 0x00004000U
#define AR_PRESELECT_USER_PIPE 0x00008000U
/*
* Audit data is generated as a stream of struct audit_record structures,
* linked by struct kaudit_record, and contain storage for possible audit so
* that it will not need to be allocated during the processing of a system
* call, both improving efficiency and avoiding sleeping at untimely moments.
* This structure is converted to BSM format before being written to disk.
*/
struct vnode_au_info {
mode_t vn_mode;
uid_t vn_uid;
gid_t vn_gid;
dev_t vn_dev;
long vn_fsid;
long vn_fileid;
long vn_gen;
};
struct groupset {
gid_t *gidset;
u_int gidset_size;
};
struct socket_au_info {
int so_domain;
int so_type;
int so_protocol;
in_addr_t so_raddr; /* Remote address if INET socket. */
in_addr_t so_laddr; /* Local address if INET socket. */
u_short so_rport; /* Remote port. */
u_short so_lport; /* Local port. */
};
/*
* The following is used for A_OLDSETQCTRL and AU_OLDGETQCTRL and a 64-bit
* userland.
*/
struct au_qctrl64 {
u_int64_t aq64_hiwater;
u_int64_t aq64_lowater;
u_int64_t aq64_bufsz;
u_int64_t aq64_delay;
u_int64_t aq64_minfree;
};
typedef struct au_qctrl64 au_qctrl64_t;
union auditon_udata {
char *au_path;
int au_cond;
int au_flags;
int au_policy;
int au_trigger;
int64_t au_cond64;
int64_t au_policy64;
au_evclass_map_t au_evclass;
au_mask_t au_mask;
auditinfo_t au_auinfo;
auditpinfo_t au_aupinfo;
auditpinfo_addr_t au_aupinfo_addr;
au_qctrl_t au_qctrl;
au_qctrl64_t au_qctrl64;
au_stat_t au_stat;
au_fstat_t au_fstat;
auditinfo_addr_t au_kau_info;
};
struct posix_ipc_perm {
uid_t pipc_uid;
gid_t pipc_gid;
mode_t pipc_mode;
};
struct audit_record {
/* Audit record header. */
u_int32_t ar_magic;
int ar_event;
int ar_retval; /* value returned to the process */
int ar_errno; /* return status of system call */
struct timespec ar_starttime;
struct timespec ar_endtime;
u_int64_t ar_valid_arg; /* Bitmask of valid arguments */
/* Audit subject information. */
struct xucred ar_subj_cred;
uid_t ar_subj_ruid;
gid_t ar_subj_rgid;
gid_t ar_subj_egid;
uid_t ar_subj_auid; /* Audit user ID */
pid_t ar_subj_asid; /* Audit session ID */
pid_t ar_subj_pid;
struct au_tid ar_subj_term;
Fix the handling of IPv6 addresses for subject and process BSM audit tokens. Currently, we do not support the set{get}audit_addr(2) system calls which allows processes like sshd to set extended or ip6 information for subject tokens. The approach that was taken was to change the process audit state slightly to use an extended terminal ID in the kernel. This allows us to store both IPv4 IPv6 addresses. In the case that an IPv4 address is in use, we convert the terminal ID from an struct auditinfo_addr to a struct auditinfo. If getaudit(2) is called when the subject is bound to an ip6 address, we return E2BIG. - Change the internal audit record to store an extended terminal ID - Introduce ARG_TERMID_ADDR - Change the kaudit <-> BSM conversion process so that we are using the appropriate subject token. If the address associated with the subject is IPv4, we use the standard subject32 token. If the subject has an IPv6 address associated with them, we use an extended subject32 token. - Fix a couple of endian issues where we do a couple of byte swaps when we shouldn't be. IP addresses are already in the correct byte order, so reading the ip6 address 4 bytes at a time and swapping them results in in-correct address data. It should be noted that the same issue was found in the openbsm library and it has been changed there too on the vendor branch - Change A_GETPINFO to use the appropriate structures - Implement A_GETPINFO_ADDR which basically does what A_GETPINFO does, but can also handle ip6 addresses - Adjust get{set}audit(2) syscalls to convert the data auditinfo <-> auditinfo_addr - Fully implement set{get}audit_addr(2) NOTE: This adds the ability for processes to correctly set extended subject information. The appropriate userspace utilities still need to be updated. MFC after: 1 month Reviewed by: rwatson Obtained from: TrustedBSD
2007-04-13 14:55:19 +00:00
struct au_tid_addr ar_subj_term_addr;
struct au_mask ar_subj_amask;
/* Operation arguments. */
uid_t ar_arg_euid;
uid_t ar_arg_ruid;
uid_t ar_arg_suid;
gid_t ar_arg_egid;
gid_t ar_arg_rgid;
gid_t ar_arg_sgid;
pid_t ar_arg_pid;
pid_t ar_arg_asid;
struct au_tid ar_arg_termid;
Fix the handling of IPv6 addresses for subject and process BSM audit tokens. Currently, we do not support the set{get}audit_addr(2) system calls which allows processes like sshd to set extended or ip6 information for subject tokens. The approach that was taken was to change the process audit state slightly to use an extended terminal ID in the kernel. This allows us to store both IPv4 IPv6 addresses. In the case that an IPv4 address is in use, we convert the terminal ID from an struct auditinfo_addr to a struct auditinfo. If getaudit(2) is called when the subject is bound to an ip6 address, we return E2BIG. - Change the internal audit record to store an extended terminal ID - Introduce ARG_TERMID_ADDR - Change the kaudit <-> BSM conversion process so that we are using the appropriate subject token. If the address associated with the subject is IPv4, we use the standard subject32 token. If the subject has an IPv6 address associated with them, we use an extended subject32 token. - Fix a couple of endian issues where we do a couple of byte swaps when we shouldn't be. IP addresses are already in the correct byte order, so reading the ip6 address 4 bytes at a time and swapping them results in in-correct address data. It should be noted that the same issue was found in the openbsm library and it has been changed there too on the vendor branch - Change A_GETPINFO to use the appropriate structures - Implement A_GETPINFO_ADDR which basically does what A_GETPINFO does, but can also handle ip6 addresses - Adjust get{set}audit(2) syscalls to convert the data auditinfo <-> auditinfo_addr - Fully implement set{get}audit_addr(2) NOTE: This adds the ability for processes to correctly set extended subject information. The appropriate userspace utilities still need to be updated. MFC after: 1 month Reviewed by: rwatson Obtained from: TrustedBSD
2007-04-13 14:55:19 +00:00
struct au_tid_addr ar_arg_termid_addr;
uid_t ar_arg_uid;
uid_t ar_arg_auid;
gid_t ar_arg_gid;
struct groupset ar_arg_groups;
int ar_arg_fd;
int ar_arg_atfd1;
int ar_arg_atfd2;
int ar_arg_fflags;
mode_t ar_arg_mode;
int ar_arg_dev;
long ar_arg_value;
void * ar_arg_addr;
int ar_arg_len;
int ar_arg_mask;
u_int ar_arg_signum;
char ar_arg_login[MAXLOGNAME];
int ar_arg_ctlname[CTL_MAXNAME];
struct socket_au_info ar_arg_sockinfo;
char *ar_arg_upath1;
char *ar_arg_upath2;
char *ar_arg_text;
struct au_mask ar_arg_amask;
struct vnode_au_info ar_arg_vnode1;
struct vnode_au_info ar_arg_vnode2;
int ar_arg_cmd;
int ar_arg_svipc_cmd;
struct ipc_perm ar_arg_svipc_perm;
int ar_arg_svipc_id;
void * ar_arg_svipc_addr;
struct posix_ipc_perm ar_arg_pipc_perm;
union auditon_udata ar_arg_auditon;
char *ar_arg_argv;
int ar_arg_argc;
char *ar_arg_envv;
int ar_arg_envc;
int ar_arg_exitstatus;
int ar_arg_exitretval;
struct sockaddr_storage ar_arg_sockaddr;
};
/*
* Arguments in the audit record are initially not defined; flags are set to
* indicate if they are present so they can be included in the audit log
* stream only if defined.
*/
#define ARG_EUID 0x0000000000000001ULL
#define ARG_RUID 0x0000000000000002ULL
#define ARG_SUID 0x0000000000000004ULL
#define ARG_EGID 0x0000000000000008ULL
#define ARG_RGID 0x0000000000000010ULL
#define ARG_SGID 0x0000000000000020ULL
#define ARG_PID 0x0000000000000040ULL
#define ARG_UID 0x0000000000000080ULL
#define ARG_AUID 0x0000000000000100ULL
#define ARG_GID 0x0000000000000200ULL
#define ARG_FD 0x0000000000000400ULL
#define ARG_POSIX_IPC_PERM 0x0000000000000800ULL
#define ARG_FFLAGS 0x0000000000001000ULL
#define ARG_MODE 0x0000000000002000ULL
#define ARG_DEV 0x0000000000004000ULL
#define ARG_ADDR 0x0000000000008000ULL
#define ARG_LEN 0x0000000000010000ULL
#define ARG_MASK 0x0000000000020000ULL
#define ARG_SIGNUM 0x0000000000040000ULL
#define ARG_LOGIN 0x0000000000080000ULL
#define ARG_SADDRINET 0x0000000000100000ULL
#define ARG_SADDRINET6 0x0000000000200000ULL
#define ARG_SADDRUNIX 0x0000000000400000ULL
#define ARG_TERMID_ADDR 0x0000000000400000ULL
#define ARG_UNUSED2 0x0000000001000000ULL
#define ARG_UPATH1 0x0000000002000000ULL
#define ARG_UPATH2 0x0000000004000000ULL
#define ARG_TEXT 0x0000000008000000ULL
#define ARG_VNODE1 0x0000000010000000ULL
#define ARG_VNODE2 0x0000000020000000ULL
#define ARG_SVIPC_CMD 0x0000000040000000ULL
#define ARG_SVIPC_PERM 0x0000000080000000ULL
#define ARG_SVIPC_ID 0x0000000100000000ULL
#define ARG_SVIPC_ADDR 0x0000000200000000ULL
#define ARG_GROUPSET 0x0000000400000000ULL
#define ARG_CMD 0x0000000800000000ULL
#define ARG_SOCKINFO 0x0000001000000000ULL
#define ARG_ASID 0x0000002000000000ULL
#define ARG_TERMID 0x0000004000000000ULL
#define ARG_AUDITON 0x0000008000000000ULL
#define ARG_VALUE 0x0000010000000000ULL
#define ARG_AMASK 0x0000020000000000ULL
#define ARG_CTLNAME 0x0000040000000000ULL
#define ARG_PROCESS 0x0000080000000000ULL
#define ARG_MACHPORT1 0x0000100000000000ULL
#define ARG_MACHPORT2 0x0000200000000000ULL
#define ARG_EXIT 0x0000400000000000ULL
#define ARG_IOVECSTR 0x0000800000000000ULL
#define ARG_ARGV 0x0001000000000000ULL
#define ARG_ENVV 0x0002000000000000ULL
#define ARG_ATFD1 0x0004000000000000ULL
#define ARG_ATFD2 0x0008000000000000ULL
#define ARG_NONE 0x0000000000000000ULL
#define ARG_ALL 0xFFFFFFFFFFFFFFFFULL
#define ARG_IS_VALID(kar, arg) ((kar)->k_ar.ar_valid_arg & (arg))
#define ARG_SET_VALID(kar, arg) do { \
(kar)->k_ar.ar_valid_arg |= (arg); \
} while (0)
#define ARG_CLEAR_VALID(kar, arg) do { \
(kar)->k_ar.ar_valid_arg &= ~(arg); \
} while (0)
/*
* In-kernel version of audit record; the basic record plus queue meta-data.
* This record can also have a pointer set to some opaque data that will be
* passed through to the audit writing mechanism.
*/
struct kaudit_record {
struct audit_record k_ar;
u_int32_t k_ar_commit;
void *k_udata; /* User data. */
u_int k_ulen; /* User data length. */
struct uthread *k_uthread; /* Audited thread. */
TAILQ_ENTRY(kaudit_record) k_q;
};
TAILQ_HEAD(kaudit_queue, kaudit_record);
/*
* Functions to manage the allocation, release, and commit of kernel audit
* records.
*/
void audit_abort(struct kaudit_record *ar);
void audit_commit(struct kaudit_record *ar, int error,
int retval);
struct kaudit_record *audit_new(int event, struct thread *td);
/*
* Functions relating to the conversion of internal kernel audit records to
* the BSM file format.
*/
struct au_record;
int kaudit_to_bsm(struct kaudit_record *kar, struct au_record **pau);
int bsm_rec_verify(void *rec);
/*
* Kernel versions of the libbsm audit record functions.
*/
void kau_free(struct au_record *rec);
void kau_init(void);
/*
* Return values for pre-selection and post-selection decisions.
*/
#define AU_PRS_SUCCESS 1
#define AU_PRS_FAILURE 2
#define AU_PRS_BOTH (AU_PRS_SUCCESS|AU_PRS_FAILURE)
/*
* Data structures relating to the kernel audit queue. Ideally, these might
* be abstracted so that only accessor methods are exposed.
*/
extern struct mtx audit_mtx;
extern struct cv audit_watermark_cv;
extern struct cv audit_worker_cv;
extern struct kaudit_queue audit_q;
extern int audit_q_len;
extern int audit_pre_q_len;
extern int audit_in_failure;
/*
* Flags to use on audit files when opening and closing.
*/
#define AUDIT_OPEN_FLAGS (FWRITE | O_APPEND)
#define AUDIT_CLOSE_FLAGS (FWRITE | O_APPEND)
#include <sys/fcntl.h>
#include <sys/kernel.h>
#include <sys/malloc.h>
/*
* Some of the BSM tokenizer functions take different parameters in the
* kernel implementations in order to save the copying of large kernel data
* structures. The prototypes of these functions are declared here.
*/
token_t *kau_to_socket(struct socket_au_info *soi);
/*
* audit_klib prototypes
*/
Introduce support for per-audit pipe preselection independent from the global audit trail configuration. This allows applications consuming audit trails to specify parameters for which audit records are of interest, including selecting records not required by the global trail. Allowing application interest specification without changing the global configuration allows intrusion detection systems to run without interfering with global auditing or each other (if multiple are present). To implement this: - Kernel audit records now carry a flag to indicate whether they have been selected by the global trail or by the audit pipe subsystem, set during record commit, so that this information is available after BSM conversion when delivering the BSM to the trail and audit pipes in the audit worker thread asynchronously. Preselection by either record target will cause the record to be kept. - Similar changes to preselection when the audit record is created when the system call is entering: consult both the global trail and pipes. - au_preselect() now accepts the class in order to avoid repeatedly looking up the mask for each preselection test. - Define a series of ioctls that allow applications to specify whether they want to track the global trail, or program their own preselection parameters: they may specify their own flags and naflags masks, similar to the global masks of the same name, as well as a set of per-auid masks. They also set a per-pipe mode specifying whether they track the global trail, or user their own -- the door is left open for future additional modes. A new ioctl is defined to allow a user process to flush the current audit pipe queue, which can be used after reprogramming pre-selection to make sure that only records of interest are received in future reads. - Audit pipe data structures are extended to hold the additional fields necessary to support preselection. By default, audit pipes track the global trail, so "praudit /dev/auditpipe" will track the global audit trail even though praudit doesn't program the audit pipe selection model. - Comment about the complexities of potentially adding partial read support to audit pipes. By using a set of ioctls, applications can select which records are of interest, and toggle the preselection mode. Obtained from: TrustedBSD Project
2006-06-05 14:48:17 +00:00
int au_preselect(au_event_t event, au_class_t class,
au_mask_t *mask_p, int sorf);
void au_evclassmap_init(void);
void au_evclassmap_insert(au_event_t event, au_class_t class);
au_class_t au_event_class(au_event_t event);
au_event_t audit_ctlname_to_sysctlevent(int name[], uint64_t valid_arg);
au_event_t audit_flags_and_error_to_openevent(int oflags, int error);
au_event_t audit_flags_and_error_to_openatevent(int oflags, int error);
au_event_t audit_msgctl_to_event(int cmd);
au_event_t audit_semctl_to_event(int cmr);
void audit_canon_path(struct thread *td, char *path, char *cpath);
au_event_t auditon_command_event(int cmd);
/*
* Audit trigger events notify user space of kernel audit conditions
* asynchronously.
*/
void audit_trigger_init(void);
int audit_send_trigger(unsigned int trigger);
/*
* Accessor functions to manage global audit state.
*/
void audit_set_kinfo(struct auditinfo_addr *);
void audit_get_kinfo(struct auditinfo_addr *);
/*
* General audit related functions.
*/
struct kaudit_record *currecord(void);
void audit_free(struct kaudit_record *ar);
void audit_shutdown(void *arg, int howto);
void audit_rotate_vnode(struct ucred *cred,
struct vnode *vp);
void audit_worker_init(void);
/*
* Audit pipe functions.
*/
Introduce support for per-audit pipe preselection independent from the global audit trail configuration. This allows applications consuming audit trails to specify parameters for which audit records are of interest, including selecting records not required by the global trail. Allowing application interest specification without changing the global configuration allows intrusion detection systems to run without interfering with global auditing or each other (if multiple are present). To implement this: - Kernel audit records now carry a flag to indicate whether they have been selected by the global trail or by the audit pipe subsystem, set during record commit, so that this information is available after BSM conversion when delivering the BSM to the trail and audit pipes in the audit worker thread asynchronously. Preselection by either record target will cause the record to be kept. - Similar changes to preselection when the audit record is created when the system call is entering: consult both the global trail and pipes. - au_preselect() now accepts the class in order to avoid repeatedly looking up the mask for each preselection test. - Define a series of ioctls that allow applications to specify whether they want to track the global trail, or program their own preselection parameters: they may specify their own flags and naflags masks, similar to the global masks of the same name, as well as a set of per-auid masks. They also set a per-pipe mode specifying whether they track the global trail, or user their own -- the door is left open for future additional modes. A new ioctl is defined to allow a user process to flush the current audit pipe queue, which can be used after reprogramming pre-selection to make sure that only records of interest are received in future reads. - Audit pipe data structures are extended to hold the additional fields necessary to support preselection. By default, audit pipes track the global trail, so "praudit /dev/auditpipe" will track the global audit trail even though praudit doesn't program the audit pipe selection model. - Comment about the complexities of potentially adding partial read support to audit pipes. By using a set of ioctls, applications can select which records are of interest, and toggle the preselection mode. Obtained from: TrustedBSD Project
2006-06-05 14:48:17 +00:00
int audit_pipe_preselect(au_id_t auid, au_event_t event,
au_class_t class, int sorf, int trail_select);
void audit_pipe_submit(au_id_t auid, au_event_t event, au_class_t class,
int sorf, int trail_select, void *record, u_int record_len);
void audit_pipe_submit_user(void *record, u_int record_len);
#endif /* ! _SECURITY_AUDIT_PRIVATE_H_ */