seccomp_rule_add(3) — Linux manual page

NAME | SYNOPSIS | DESCRIPTION | RETURN VALUE | EXAMPLES | NOTES | BUGS | AUTHOR | SEE ALSO | COLOPHON

seccomp_rule_add(3)     libseccomp Documentation     seccomp_rule_add(3)

NAME         top

       seccomp_rule_add, seccomp_rule_add_exact - Add a seccomp filter
       rule

SYNOPSIS         top

       #include <seccomp.h>

       typedef void * scmp_filter_ctx;

       int SCMP_SYS(syscall_name);

       struct scmp_arg_cmp SCMP_CMP(unsigned int arg,
                                    enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A0(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A1(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A2(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A3(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A4(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A5(enum scmp_compare op, ...);

       struct scmp_arg_cmp SCMP_CMP64(unsigned int arg,
                                    enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A0_64(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A1_64(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A2_64(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A3_64(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A4_64(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A5_64(enum scmp_compare op, ...);

       struct scmp_arg_cmp SCMP_CMP32(unsigned int arg,
                                    enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A0_32(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A1_32(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A2_32(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A3_32(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A4_32(enum scmp_compare op, ...);
       struct scmp_arg_cmp SCMP_A5_32(enum scmp_compare op, ...);

       int seccomp_rule_add(scmp_filter_ctx ctx, uint32_t action,
                            int syscall, unsigned int arg_cnt, ...);
       int seccomp_rule_add_exact(scmp_filter_ctx ctx, uint32_t action,
                                  int syscall, unsigned int arg_cnt, ...);

       int seccomp_rule_add_array(scmp_filter_ctx ctx,
                                  uint32_t action, int syscall,
                                  unsigned int arg_cnt,
                                  const struct scmp_arg_cmp *arg_array);
       int seccomp_rule_add_exact_array(scmp_filter_ctx ctx,
                                        uint32_t action, int syscall,
                                        unsigned int arg_cnt,
                                        const struct scmp_arg_cmp *arg_array);

       Link with -lseccomp.

DESCRIPTION         top

       The seccomp_rule_add(), seccomp_rule_add_array(),
       seccomp_rule_add_exact(), and seccomp_rule_add_exact_array()
       functions all add a new filter rule to the current seccomp
       filter.  The seccomp_rule_add() and seccomp_rule_add_array()
       functions will make a "best effort" to add the rule as specified,
       but may alter the rule slightly due to architecture specifics
       (e.g. internal rewriting of multiplexed syscalls, like socket and
       ipc functions on x86).  The seccomp_rule_add_exact() and
       seccomp_rule_add_exact_array() functions will attempt to add the
       rule exactly as specified so it may behave differently on
       different architectures.  While it does not guarantee a exact
       filter ruleset, seccomp_rule_add() and seccomp_rule_add_array()
       do guarantee the same behavior regardless of the architecture.

       The newly added filter rule does not take effect until the entire
       filter is loaded into the kernel using seccomp_load(3).  When
       adding rules to a filter, it is important to consider the impact
       of previously loaded filters; see the seccomp_load(3)
       documentation for more information.

       All of the filter rules supplied by the calling application are
       combined into a union, with additional logic to eliminate
       redundant syscall filters.  For example, if a rule is added which
       allows a given syscall with a specific set of argument values and
       later a rule is added which allows the same syscall regardless
       the argument values then the first, more specific rule, is
       effectively dropped from the filter by the second more generic
       rule.

       The SCMP_CMP(), SCMP_CMP64(), SCMP_A{0-5}(), and SCMP_A{0-5}_64()
       macros generate a scmp_arg_cmp structure for use with the above
       functions. The SCMP_CMP() and SCMP_CMP64() macros allows the
       caller to specify an arbitrary argument along with the comparison
       operator, 64-bit mask, and 64-bit datum values where the
       SCMP_A{0-5}() and SCMP_A{0-5}_64() macros are specific to a
       certain argument.

       The SCMP_CMP32() and SCMP_A{0-5}_32() macros are similar to the
       variants above, but they take 32-bit mask and 32-bit datum
       values.

       It is recommended that whenever possible developers avoid using
       the SCMP_CMP() and SCMP_A{0-5}() macros and use the variants
       which are explicitly 32 or 64-bit.  This should help eliminate
       problems caused by an unwanted sign extension of negative datum
       values.

       If syscall argument comparisons are included in the filter rule,
       all of the comparisons must be true for the rule to match.

       When adding syscall argument comparisons to the filter it is
       important to remember that while it is possible to have multiple
       comparisons in a single rule, you can only compare each argument
       once in a single rule.  In other words, you can not have multiple
       comparisons of the 3rd syscall argument in a single rule.

       In a filter containing multiple architectures, it is an error to
       add a filter rule for a syscall that does not exist in all of the
       filter's architectures.

       While it is possible to specify the syscall value directly using
       the standard __NR_syscall values, in order to ensure proper
       operation across multiple architectures it is highly recommended
       to use the SCMP_SYS() macro instead.  See the EXAMPLES section
       below.  It is also important to remember that regardless of the
       architectures present in the filter, the syscall numbers used in
       filter rules are interpreted in the context of the native
       architecture.

       Starting with Linux v4.8, there may be a need to create a rule
       with a syscall value of -1 to allow tracing programs to skip a
       syscall invocation; in order to create a rule with a -1 syscall
       value it is necessary to first set the SCMP_FLTATR_API_TSKIP
       attribute.  See seccomp_attr_set(3) for more information.

       The filter context ctx is the value returned by the call to
       seccomp_init(3).

       Valid action values are as follows:

       SCMP_ACT_KILL
              The thread will be killed by the kernel when it calls a
              syscall that matches the filter rule.

       SCMP_ACT_KILL_PROCESS
              The process will be killed by the kernel when it calls a
              syscall that matches the filter rule.

       SCMP_ACT_TRAP
              The thread will throw a SIGSYS signal when it calls a
              syscall that matches the filter rule.

       SCMP_ACT_ERRNO(uint16_t errno)
              The thread will receive a return value of errno when it
              calls a syscall that matches the filter rule.

       SCMP_ACT_TRACE(uint16_t msg_num)
              If the thread is being traced and the tracing process
              specified the PTRACE_O_TRACESECCOMP option in the call to
              ptrace(2), the tracing process will be notified, via
              PTRACE_EVENT_SECCOMP , and the value provided in msg_num
              can be retrieved using the PTRACE_GETEVENTMSG option.

       SCMP_ACT_LOG
              The seccomp filter will have no effect on the thread
              calling the syscall if it matches the filter rule but the
              syscall will be logged.

       SCMP_ACT_ALLOW
              The seccomp filter will have no effect on the thread
              calling the syscall if it matches the filter rule.

       SCMP_ACT_NOTIFY
              A monitoring process will be notified when a process
              running the seccomp filter calls a syscall that matches
              the filter rule.  The process that invokes the syscall
              waits in the kernel until the monitoring process has
              responded via seccomp_notify_respond(3) .

              When a filter utilizing SCMP_ACT_NOTIFY is loaded into the
              kernel, the kernel generates a notification fd that must
              be used to communicate between the monitoring process and
              the process(es) being filtered.  See seccomp_notify_fd(3)
              for more information.

       Valid comparison op values are as follows:

       SCMP_CMP_NE
              Matches when the argument value is not equal to the datum
              value, example:

              SCMP_CMP( arg , SCMP_CMP_NE , datum )

       SCMP_CMP_LT
              Matches when the argument value is less than the datum
              value, example:

              SCMP_CMP( arg , SCMP_CMP_LT , datum )

       SCMP_CMP_LE
              Matches when the argument value is less than or equal to
              the datum value, example:

              SCMP_CMP( arg , SCMP_CMP_LE , datum )

       SCMP_CMP_EQ
              Matches when the argument value is equal to the datum
              value, example:

              SCMP_CMP( arg , SCMP_CMP_EQ , datum )

       SCMP_CMP_GE
              Matches when the argument value is greater than or equal
              to the datum value, example:

              SCMP_CMP( arg , SCMP_CMP_GE , datum )

       SCMP_CMP_GT
              Matches when the argument value is greater than the datum
              value, example:

              SCMP_CMP( arg , SCMP_CMP_GT , datum )

       SCMP_CMP_MASKED_EQ
              Matches when the masked argument value is equal to the
              masked datum value, example:

              SCMP_CMP( arg , SCMP_CMP_MASKED_EQ , mask , datum )

RETURN VALUE         top

       The SCMP_SYS() macro returns a value suitable for use as the
       syscall value in the seccomp_rule_add*() functions.  In a similar
       manner, the SCMP_CMP() and SCMP_A*() macros return values
       suitable for use as argument comparisons in the
       seccomp_rule_add() and seccomp_rule_add_exact() functions.

       The seccomp_rule_add(), seccomp_rule_add_array(),
       seccomp_rule_add_exact(), and seccomp_rule_add_exact_array()
       functions return zero on success or one of the following error
       codes on failure:

       -EDOM  Architecture specific failure.

       -EEXIST
              The rule already exists.

       -EACCES
              The rule conflicts with the filter (for example, the rule
              action equals the default action of the filter).

       -EFAULT
              Internal libseccomp failure.

       -EINVAL
              Invalid input, either the context or architecture token is
              invalid.

       -ENOMEM
              The library was unable to allocate enough memory.

       -EOPNOTSUPP
              The library doesn't support the particular operation.

EXAMPLES         top

       #include <fcntl.h>
       #include <seccomp.h>
       #include <sys/stat.h>
       #include <sys/types.h>
       #include <stddef.h>

       #define BUF_SIZE    256

       int main(int argc, char *argv[])
       {
            int rc = -1;
            scmp_filter_ctx ctx;
            struct scmp_arg_cmp arg_cmp[] = { SCMP_A0(SCMP_CMP_EQ, 2) };
            int fd;
            unsigned char buf[BUF_SIZE];

            ctx = seccomp_init(SCMP_ACT_KILL);
            if (ctx == NULL)
                 goto out;

            /* ... */

            fd = open("file.txt", 0);

            /* ... */

            rc = seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(close), 0);
            if (rc < 0)
                 goto out;

            rc = seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(exit_group), 0);
            if (rc < 0)
                 goto out;

            rc = seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(exit), 0);
            if (rc < 0)
                 goto out;

            rc = seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(read), 3,
                            SCMP_A0(SCMP_CMP_EQ, fd),
                            SCMP_A1(SCMP_CMP_EQ, (scmp_datum_t)buf),
                            SCMP_A2(SCMP_CMP_LE, BUF_SIZE));
            if (rc < 0)
                 goto out;

            rc = seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(write), 1,
                            SCMP_CMP(0, SCMP_CMP_EQ, fd));
            if (rc < 0)
                 goto out;

            rc = seccomp_rule_add_array(ctx, SCMP_ACT_ALLOW, SCMP_SYS(write), 1,
                                  arg_cmp);
            if (rc < 0)
                 goto out;

            rc = seccomp_load(ctx);
            if (rc < 0)
                 goto out;

            /* ... */

       out:
            seccomp_release(ctx);
            return -rc;
       }

NOTES         top

       While the seccomp filter can be generated independent of the
       kernel, kernel support is required to load and enforce the
       seccomp filter generated by libseccomp.

       The libseccomp project site, with more information and the source
       code repository, can be found at
       https://github.com/seccomp/libseccomp.  This tool, as well as the
       libseccomp library, is currently under development, please report
       any bugs at the project site or directly to the author.

BUGS         top

       The runtime behavior of seccomp filters is dependent upon the
       kernel version, the processor architecture, and other libraries
       including libc.  This could affect the return code of a seccomp
       filter.

       *      PowerPC glibc will not return a negative number when the
              getpid() syscall is invoked.  If a seccomp filter has been
              created where getpid() will return a negative number from
              the kernel, then PowerPC glibc will return the absolute
              value of the errno.  In this case, it is very difficult
              for an application to distinguish between the errno and a
              valid pid.

AUTHOR         top

       Paul Moore <[email protected]>

SEE ALSO         top

       seccomp_syscall_resolve_name_rewrite(3),
       seccomp_syscall_priority(3), seccomp_load(3), seccomp_attr_set(3)

COLOPHON         top

       This page is part of the libseccomp (high-level API to the Linux
       Kernel's seccomp filter) project.  Information about the project
       can be found at ⟨https://github.com/seccomp/libseccomp⟩.  If you
       have a bug report for this manual page, see
       ⟨https://groups.google.com/d/forum/libseccomp⟩.  This page was
       obtained from the project's upstream Git repository
       ⟨https://github.com/seccomp/libseccomp⟩ on 2024-06-14.  (At that
       time, the date of the most recent commit that was found in the
       repository was 2024-04-18.)  If you discover any rendering
       problems in this HTML version of the page, or you believe there
       is a better or more up-to-date source for the page, or you have
       corrections or improvements to the information in this COLOPHON
       (which is not part of the original manual page), send a mail to
       [email protected]

[email protected]            30 May 2020           seccomp_rule_add(3)

Pages that refer to this page: seccomp(2)seccomp_load(3)seccomp_syscall_priority(3)seccomp_syscall_resolve_name(3)