Documentation/bpf/bpf_iterators.rst - linux/kernel/git/mellanox/linux - Git at Google

 =============
 BPF Iterators
 =============


 ----------
 Motivation
 ----------

 There are a few existing ways to dump kernel data into user space. The most
 popular one is the ``/proc`` system. For example, ``cat /proc/net/tcp6`` dumps
 all tcp6 sockets in the system, and ``cat /proc/net/netlink`` dumps all netlink
 sockets in the system. However, their output format tends to be fixed, and if
 users want more information about these sockets, they have to patch the kernel,
 which often takes time to publish upstream and release. The same is true for popular
 tools like `ss <https://man7.org/linux/man-pages/man8/ss.8.html>`_ where any
 additional information needs a kernel patch.

 To solve this problem, the `drgn
 <https://www.kernel.org/doc/html/latest/bpf/drgn.html>`_ tool is often used to
 dig out the kernel data with no kernel change. However, the main drawback for
 drgn is performance, as it cannot do pointer tracing inside the kernel. In
 addition, drgn cannot validate a pointer value and may read invalid data if the
 pointer becomes invalid inside the kernel.

 The BPF iterator solves the above problem by providing flexibility on what data
 (e.g., tasks, bpf_maps, etc.) to collect by calling BPF programs for each kernel
 data object.

 ----------------------
 How BPF Iterators Work
 ----------------------

 A BPF iterator is a type of BPF program that allows users to iterate over
 specific types of kernel objects. Unlike traditional BPF tracing programs that
 allow users to define callbacks that are invoked at particular points of
 execution in the kernel, BPF iterators allow users to define callbacks that
 should be executed for every entry in a variety of kernel data structures.

 For example, users can define a BPF iterator that iterates over every task on
 the system and dumps the total amount of CPU runtime currently used by each of
 them. Another BPF task iterator may instead dump the cgroup information for each
 task. Such flexibility is the core value of BPF iterators.

 A BPF program is always loaded into the kernel at the behest of a user space
 process. A user space process loads a BPF program by opening and initializing
 the program skeleton as required and then invoking a syscall to have the BPF
 program verified and loaded by the kernel.

 In traditional tracing programs, a program is activated by having user space
 obtain a ``bpf_link`` to the program with ``bpf_program__attach()``. Once
 activated, the program callback will be invoked whenever the tracepoint is
 triggered in the main kernel. For BPF iterator programs, a ``bpf_link`` to the
 program is obtained using ``bpf_link_create()``, and the program callback is
 invoked by issuing system calls from user space.

 Next, let us see how you can use the iterators to iterate on kernel objects and
 read data.

 ------------------------
 How to Use BPF iterators
 ------------------------

 BPF selftests are a great resource to illustrate how to use the iterators. In
 this section, we’ll walk through a BPF selftest which shows how to load and use
 a BPF iterator program.   To begin, we’ll look at `bpf_iter.c
 <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/prog_tests/bpf_iter.c>`_,
 which illustrates how to load and trigger BPF iterators on the user space side.
 Later, we’ll look at a BPF program that runs in kernel space.

 Loading a BPF iterator in the kernel from user space typically involves the
 following steps:

 * The BPF program is loaded into the kernel through ``libbpf``. Once the kernel
   has verified and loaded the program, it returns a file descriptor (fd) to user
   space.
 * Obtain a ``link_fd`` to the BPF program by calling the ``bpf_link_create()``
   specified with the BPF program file descriptor received from the kernel.
 * Next, obtain a BPF iterator file descriptor (``bpf_iter_fd``) by calling the
   ``bpf_iter_create()`` specified with the ``bpf_link`` received from Step 2.
 * Trigger the iteration by calling ``read(bpf_iter_fd)`` until no data is
   available.
 * Close the iterator fd using ``close(bpf_iter_fd)``.
 * If needed to reread the data, get a new ``bpf_iter_fd`` and do the read again.

 The following are a few examples of selftest BPF iterator programs:

 * `bpf_iter_tcp4.c <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/progs/bpf_iter_tcp4.c>`_
 * `bpf_iter_task_vma.c <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/progs/bpf_iter_task_vma.c>`_
 * `bpf_iter_task_file.c <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/progs/bpf_iter_task_file.c>`_

 Let us look at ``bpf_iter_task_file.c``, which runs in kernel space:

 Here is the definition of ``bpf_iter__task_file`` in `vmlinux.h
 <https://facebookmicrosites.github.io/bpf/blog/2020/02/19/bpf-portability-and-co-re.html#btf>`_.
 Any struct name in ``vmlinux.h`` in the format ``bpf_iter__<iter_name>``
 represents a BPF iterator. The suffix ``<iter_name>`` represents the type of
 iterator.

 ::

     struct bpf_iter__task_file {
             union {
                 struct bpf_iter_meta *meta;
             };
             union {
                 struct task_struct *task;
             };
             u32 fd;
             union {
                 struct file *file;
             };
     };

 In the above code, the field 'meta' contains the metadata, which is the same for
 all BPF iterator programs. The rest of the fields are specific to different
 iterators. For example, for task_file iterators, the kernel layer provides the
 'task', 'fd' and 'file' field values. The 'task' and 'file' are `reference
 counted
 <https://facebookmicrosites.github.io/bpf/blog/2018/08/31/object-lifetime.html#file-descriptors-and-reference-counters>`_,
 so they won't go away when the BPF program runs.

 Here is a snippet from the  ``bpf_iter_task_file.c`` file:

 ::

   SEC("iter/task_file")
   int dump_task_file(struct bpf_iter__task_file *ctx)
   {
     struct seq_file *seq = ctx->meta->seq;
     struct task_struct *task = ctx->task;
     struct file *file = ctx->file;
     __u32 fd = ctx->fd;

     if (task == NULL || file == NULL)
       return 0;

     if (ctx->meta->seq_num == 0) {
       count = 0;
       BPF_SEQ_PRINTF(seq, "    tgid      gid       fd      file\n");
     }

     if (tgid == task->tgid && task->tgid != task->pid)
       count++;

     if (last_tgid != task->tgid) {
       last_tgid = task->tgid;
       unique_tgid_count++;
     }

     BPF_SEQ_PRINTF(seq, "%8d %8d %8d %lx\n", task->tgid, task->pid, fd,
             (long)file->f_op);
     return 0;
   }

 In the above example, the section name ``SEC(iter/task_file)``, indicates that
 the program is a BPF iterator program to iterate all files from all tasks. The
 context of the program is ``bpf_iter__task_file`` struct.

 The user space program invokes the BPF iterator program running in the kernel
 by issuing a ``read()`` syscall. Once invoked, the BPF
 program can export data to user space using a variety of BPF helper functions.
 You can use either ``bpf_seq_printf()`` (and BPF_SEQ_PRINTF helper macro) or
 ``bpf_seq_write()`` function based on whether you need formatted output or just
 binary data, respectively. For binary-encoded data, the user space applications
 can process the data from ``bpf_seq_write()`` as needed. For the formatted data,
 you can use ``cat <path>`` to print the results similar to ``cat
 /proc/net/netlink`` after pinning the BPF iterator to the bpffs mount. Later,
 use  ``rm -f <path>`` to remove the pinned iterator.

 For example, you can use the following command to create a BPF iterator from the
 ``bpf_iter_ipv6_route.o`` object file and pin it to the ``/sys/fs/bpf/my_route``
 path:

 ::

   $ bpftool iter pin ./bpf_iter_ipv6_route.o  /sys/fs/bpf/my_route

 And then print out the results using the following command:

 ::

   $ cat /sys/fs/bpf/my_route


 -------------------------------------------------------
 Implement Kernel Support for BPF Iterator Program Types
 -------------------------------------------------------

 To implement a BPF iterator in the kernel, the developer must make a one-time
 change to the following key data structure defined in the `bpf.h
 <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/include/linux/bpf.h>`_
 file.

 ::

   struct bpf_iter_reg {
             const char *target;
             bpf_iter_attach_target_t attach_target;
             bpf_iter_detach_target_t detach_target;
             bpf_iter_show_fdinfo_t show_fdinfo;
             bpf_iter_fill_link_info_t fill_link_info;
             bpf_iter_get_func_proto_t get_func_proto;
             u32 ctx_arg_info_size;
             u32 feature;
             struct bpf_ctx_arg_aux ctx_arg_info[BPF_ITER_CTX_ARG_MAX];
             const struct bpf_iter_seq_info *seq_info;
   };

 After filling the data structure fields, call ``bpf_iter_reg_target()`` to
 register the iterator to the main BPF iterator subsystem.

 The following is the breakdown for each field in struct ``bpf_iter_reg``.

 .. list-table::
    :widths: 25 50
    :header-rows: 1

    * - Fields
      - Description
    * - target
      - Specifies the name of the BPF iterator. For example: ``bpf_map``,
        ``bpf_map_elem``. The name should be different from other ``bpf_iter`` target names in the kernel.
    * - attach_target and detach_target
      - Allows for target specific ``link_create`` action since some targets
        may need special processing. Called during the user space link_create stage.
    * - show_fdinfo and fill_link_info
      - Called to fill target specific information when user tries to get link
        info associated with the iterator.
    * - get_func_proto
      - Permits a BPF iterator to access BPF helpers specific to the iterator.
    * - ctx_arg_info_size and ctx_arg_info
      - Specifies the verifier states for BPF program arguments associated with
        the bpf iterator.
    * - feature
      - Specifies certain action requests in the kernel BPF iterator
        infrastructure. Currently, only BPF_ITER_RESCHED is supported. This means
        that the kernel function cond_resched() is called to avoid other kernel
        subsystem (e.g., rcu) misbehaving.
    * - seq_info
      - Specifies the set of seq operations for the BPF iterator and helpers to
        initialize/free the private data for the corresponding ``seq_file``.

 `Click here
 <https://lore.kernel.org/bpf/20210212183107.50963-2-songliubraving@fb.com/>`_
 to see an implementation of the ``task_vma`` BPF iterator in the kernel.

 ---------------------------------
 Parameterizing BPF Task Iterators
 ---------------------------------

 By default, BPF iterators walk through all the objects of the specified types
 (processes, cgroups, maps, etc.) across the entire system to read relevant
 kernel data. But often, there are cases where we only care about a much smaller
 subset of iterable kernel objects, such as only iterating tasks within a
 specific process. Therefore, BPF iterator programs support filtering out objects
 from iteration by allowing user space to configure the iterator program when it
 is attached.

 --------------------------
 BPF Task Iterator Program
 --------------------------

 The following code is a BPF iterator program to print files and task information
 through the ``seq_file`` of the iterator. It is a standard BPF iterator program
 that visits every file of an iterator. We will use this BPF program in our
 example later.

 ::

   #include <vmlinux.h>
   #include <bpf/bpf_helpers.h>

   char _license[] SEC("license") = "GPL";

   SEC("iter/task_file")
   int dump_task_file(struct bpf_iter__task_file *ctx)
   {
         struct seq_file *seq = ctx->meta->seq;
         struct task_struct *task = ctx->task;
         struct file *file = ctx->file;
         __u32 fd = ctx->fd;
         if (task == NULL || file == NULL)
                 return 0;
         if (ctx->meta->seq_num == 0) {
                 BPF_SEQ_PRINTF(seq, "    tgid      pid       fd      file\n");
         }
         BPF_SEQ_PRINTF(seq, "%8d %8d %8d %lx\n", task->tgid, task->pid, fd,
                         (long)file->f_op);
         return 0;
   }

 ----------------------------------------
 Creating a File Iterator with Parameters
 ----------------------------------------

 Now, let us look at how to create an iterator that includes only files of a
 process.

 First,  fill the ``bpf_iter_attach_opts`` struct as shown below:

 ::

   LIBBPF_OPTS(bpf_iter_attach_opts, opts);
   union bpf_iter_link_info linfo;
   memset(&linfo, 0, sizeof(linfo));
   linfo.task.pid = getpid();
   opts.link_info = &linfo;
   opts.link_info_len = sizeof(linfo);

 ``linfo.task.pid``, if it is non-zero, directs the kernel to create an iterator
 that only includes opened files for the process with the specified ``pid``. In
 this example, we will only be iterating files for our process. If
 ``linfo.task.pid`` is zero, the iterator will visit every opened file of every
 process. Similarly, ``linfo.task.tid`` directs the kernel to create an iterator
 that visits opened files of a specific thread, not a process. In this example,
 ``linfo.task.tid`` is different from ``linfo.task.pid`` only if the thread has a
 separate file descriptor table. In most circumstances, all process threads share
 a single file descriptor table.

 Now, in the userspace program, pass the pointer of struct to the
 ``bpf_program__attach_iter()``.

 ::

   link = bpf_program__attach_iter(prog, &opts); iter_fd =
   bpf_iter_create(bpf_link__fd(link));

 If both *tid* and *pid* are zero, an iterator created from this struct
 ``bpf_iter_attach_opts`` will include every opened file of every task in the
 system (in the namespace, actually.) It is the same as passing a NULL as the
 second argument to ``bpf_program__attach_iter()``.

 The whole program looks like the following code:

 ::

   #include <stdio.h>
   #include <unistd.h>
   #include <bpf/bpf.h>
   #include <bpf/libbpf.h>
   #include "bpf_iter_task_ex.skel.h"

   static int do_read_opts(struct bpf_program *prog, struct bpf_iter_attach_opts *opts)
   {
         struct bpf_link *link;
         char buf[16] = {};
         int iter_fd = -1, len;
         int ret = 0;

         link = bpf_program__attach_iter(prog, opts);
         if (!link) {
                 fprintf(stderr, "bpf_program__attach_iter() fails\n");
                 return -1;
         }
         iter_fd = bpf_iter_create(bpf_link__fd(link));
         if (iter_fd < 0) {
                 fprintf(stderr, "bpf_iter_create() fails\n");
                 ret = -1;
                 goto free_link;
         }
         /* not check contents, but ensure read() ends without error */
         while ((len = read(iter_fd, buf, sizeof(buf) - 1)) > 0) {
                 buf[len] = 0;
                 printf("%s", buf);
         }
         printf("\n");
   free_link:
         if (iter_fd >= 0)
                 close(iter_fd);
         bpf_link__destroy(link);
         return 0;
   }

   static void test_task_file(void)
   {
         LIBBPF_OPTS(bpf_iter_attach_opts, opts);
         struct bpf_iter_task_ex *skel;
         union bpf_iter_link_info linfo;
         skel = bpf_iter_task_ex__open_and_load();
         if (skel == NULL)
                 return;
         memset(&linfo, 0, sizeof(linfo));
         linfo.task.pid = getpid();
         opts.link_info = &linfo;
         opts.link_info_len = sizeof(linfo);
         printf("PID %d\n", getpid());
         do_read_opts(skel->progs.dump_task_file, &opts);
         bpf_iter_task_ex__destroy(skel);
   }

   int main(int argc, const char * const * argv)
   {
         test_task_file();
         return 0;
   }

 The following lines are the output of the program.
 ::

   PID 1859

      tgid      pid       fd      file
      1859     1859        0 ffffffff82270aa0
      1859     1859        1 ffffffff82270aa0
      1859     1859        2 ffffffff82270aa0
      1859     1859        3 ffffffff82272980
      1859     1859        4 ffffffff8225e120
      1859     1859        5 ffffffff82255120
      1859     1859        6 ffffffff82254f00
      1859     1859        7 ffffffff82254d80
      1859     1859        8 ffffffff8225abe0

 ------------------
 Without Parameters
 ------------------

 Let us look at how a BPF iterator without parameters skips files of other
 processes in the system. In this case, the BPF program has to check the pid or
 the tid of tasks, or it will receive every opened file in the system (in the
 current *pid* namespace, actually). So, we usually add a global variable in the
 BPF program to pass a *pid* to the BPF program.

 The BPF program would look like the following block.

   ::

     ......
     int target_pid = 0;

     SEC("iter/task_file")
     int dump_task_file(struct bpf_iter__task_file *ctx)
     {
           ......
           if (task->tgid != target_pid) /* Check task->pid instead to check thread IDs */
                   return 0;
           BPF_SEQ_PRINTF(seq, "%8d %8d %8d %lx\n", task->tgid, task->pid, fd,
                           (long)file->f_op);
           return 0;
     }

 The user space program would look like the following block:

   ::

     ......
     static void test_task_file(void)
     {
           ......
           skel = bpf_iter_task_ex__open_and_load();
           if (skel == NULL)
                   return;
           skel->bss->target_pid = getpid(); /* process ID.  For thread id, use gettid() */
           memset(&linfo, 0, sizeof(linfo));
           linfo.task.pid = getpid();
           opts.link_info = &linfo;
           opts.link_info_len = sizeof(linfo);
           ......
     }

 ``target_pid`` is a global variable in the BPF program. The user space program
 should initialize the variable with a process ID to skip opened files of other
 processes in the BPF program. When you parametrize a BPF iterator, the iterator
 calls the BPF program fewer times which can save significant resources.

 ---------------------------
 Parametrizing VMA Iterators
 ---------------------------

 By default, a BPF VMA iterator includes every VMA in every process.  However,
 you can still specify a process or a thread to include only its VMAs. Unlike
 files, a thread can not have a separate address space (since Linux 2.6.0-test6).
 Here, using *tid* makes no difference from using *pid*.

 ----------------------------
 Parametrizing Task Iterators
 ----------------------------

 A BPF task iterator with *pid* includes all tasks (threads) of a process. The
 BPF program receives these tasks one after another. You can specify a BPF task
 iterator with *tid* parameter to include only the tasks that match the given
 *tid*.
	=============
	BPF Iterators
	=============


	----------
	Motivation
	----------

	There are a few existing ways to dump kernel data into user space. The most
	popular one is the ``/proc`` system. For example, ``cat /proc/net/tcp6`` dumps
	all tcp6 sockets in the system, and ``cat /proc/net/netlink`` dumps all netlink
	sockets in the system. However, their output format tends to be fixed, and if
	users want more information about these sockets, they have to patch the kernel,
	which often takes time to publish upstream and release. The same is true for popular
	tools like `ss <https://man7.org/linux/man-pages/man8/ss.8.html>`_ where any
	additional information needs a kernel patch.

	To solve this problem, the `drgn
	<https://www.kernel.org/doc/html/latest/bpf/drgn.html>`_ tool is often used to
	dig out the kernel data with no kernel change. However, the main drawback for
	drgn is performance, as it cannot do pointer tracing inside the kernel. In
	addition, drgn cannot validate a pointer value and may read invalid data if the
	pointer becomes invalid inside the kernel.

	The BPF iterator solves the above problem by providing flexibility on what data
	(e.g., tasks, bpf_maps, etc.) to collect by calling BPF programs for each kernel
	data object.

	----------------------
	How BPF Iterators Work
	----------------------

	A BPF iterator is a type of BPF program that allows users to iterate over
	specific types of kernel objects. Unlike traditional BPF tracing programs that
	allow users to define callbacks that are invoked at particular points of
	execution in the kernel, BPF iterators allow users to define callbacks that
	should be executed for every entry in a variety of kernel data structures.

	For example, users can define a BPF iterator that iterates over every task on
	the system and dumps the total amount of CPU runtime currently used by each of
	them. Another BPF task iterator may instead dump the cgroup information for each
	task. Such flexibility is the core value of BPF iterators.

	A BPF program is always loaded into the kernel at the behest of a user space
	process. A user space process loads a BPF program by opening and initializing
	the program skeleton as required and then invoking a syscall to have the BPF
	program verified and loaded by the kernel.

	In traditional tracing programs, a program is activated by having user space
	obtain a ``bpf_link`` to the program with ``bpf_program__attach()``. Once
	activated, the program callback will be invoked whenever the tracepoint is
	triggered in the main kernel. For BPF iterator programs, a ``bpf_link`` to the
	program is obtained using ``bpf_link_create()``, and the program callback is
	invoked by issuing system calls from user space.

	Next, let us see how you can use the iterators to iterate on kernel objects and
	read data.

	------------------------
	How to Use BPF iterators
	------------------------

	BPF selftests are a great resource to illustrate how to use the iterators. In
	this section, we’ll walk through a BPF selftest which shows how to load and use
	a BPF iterator program. To begin, we’ll look at `bpf_iter.c
	<https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/prog_tests/bpf_iter.c>`_,
	which illustrates how to load and trigger BPF iterators on the user space side.
	Later, we’ll look at a BPF program that runs in kernel space.

	Loading a BPF iterator in the kernel from user space typically involves the
	following steps:

	* The BPF program is loaded into the kernel through ``libbpf``. Once the kernel
	has verified and loaded the program, it returns a file descriptor (fd) to user
	space.
	* Obtain a ``link_fd`` to the BPF program by calling the ``bpf_link_create()``
	specified with the BPF program file descriptor received from the kernel.
	* Next, obtain a BPF iterator file descriptor (``bpf_iter_fd``) by calling the
	``bpf_iter_create()`` specified with the ``bpf_link`` received from Step 2.
	* Trigger the iteration by calling ``read(bpf_iter_fd)`` until no data is
	available.
	* Close the iterator fd using ``close(bpf_iter_fd)``.
	* If needed to reread the data, get a new ``bpf_iter_fd`` and do the read again.

	The following are a few examples of selftest BPF iterator programs:

	* `bpf_iter_tcp4.c <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/progs/bpf_iter_tcp4.c>`_
	* `bpf_iter_task_vma.c <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/progs/bpf_iter_task_vma.c>`_
	* `bpf_iter_task_file.c <https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/tools/testing/selftests/bpf/progs/bpf_iter_task_file.c>`_

	Let us look at ``bpf_iter_task_file.c``, which runs in kernel space:

	Here is the definition of ``bpf_iter__task_file`` in `vmlinux.h
	<https://facebookmicrosites.github.io/bpf/blog/2020/02/19/bpf-portability-and-co-re.html#btf>`_.
	Any struct name in ``vmlinux.h`` in the format ``bpf_iter__<iter_name>``
	represents a BPF iterator. The suffix ``<iter_name>`` represents the type of
	iterator.

	::

	struct bpf_iter__task_file {
	union {
	struct bpf_iter_meta *meta;
	};
	union {
	struct task_struct *task;
	};
	u32 fd;
	union {
	struct file *file;
	};
	};

	In the above code, the field 'meta' contains the metadata, which is the same for
	all BPF iterator programs. The rest of the fields are specific to different
	iterators. For example, for task_file iterators, the kernel layer provides the
	'task', 'fd' and 'file' field values. The 'task' and 'file' are `reference
	counted
	<https://facebookmicrosites.github.io/bpf/blog/2018/08/31/object-lifetime.html#file-descriptors-and-reference-counters>`_,
	so they won't go away when the BPF program runs.

	Here is a snippet from the ``bpf_iter_task_file.c`` file:

	::

	SEC("iter/task_file")
	int dump_task_file(struct bpf_iter__task_file *ctx)
	{
	struct seq_file *seq = ctx->meta->seq;
	struct task_struct *task = ctx->task;
	struct file *file = ctx->file;
	__u32 fd = ctx->fd;

	if (task == NULL \|\| file == NULL)
	return 0;

	if (ctx->meta->seq_num == 0) {
	count = 0;
	BPF_SEQ_PRINTF(seq, " tgid gid fd file\n");
	}

	if (tgid == task->tgid && task->tgid != task->pid)
	count++;

	if (last_tgid != task->tgid) {
	last_tgid = task->tgid;
	unique_tgid_count++;
	}

	BPF_SEQ_PRINTF(seq, "%8d %8d %8d %lx\n", task->tgid, task->pid, fd,
	(long)file->f_op);
	return 0;
	}

	In the above example, the section name ``SEC(iter/task_file)``, indicates that
	the program is a BPF iterator program to iterate all files from all tasks. The
	context of the program is ``bpf_iter__task_file`` struct.

	The user space program invokes the BPF iterator program running in the kernel
	by issuing a ``read()`` syscall. Once invoked, the BPF
	program can export data to user space using a variety of BPF helper functions.
	You can use either ``bpf_seq_printf()`` (and BPF_SEQ_PRINTF helper macro) or
	``bpf_seq_write()`` function based on whether you need formatted output or just
	binary data, respectively. For binary-encoded data, the user space applications
	can process the data from ``bpf_seq_write()`` as needed. For the formatted data,
	you can use ``cat <path>`` to print the results similar to ``cat
	/proc/net/netlink`` after pinning the BPF iterator to the bpffs mount. Later,
	use ``rm -f <path>`` to remove the pinned iterator.

	For example, you can use the following command to create a BPF iterator from the
	``bpf_iter_ipv6_route.o`` object file and pin it to the ``/sys/fs/bpf/my_route``
	path:

	::

	$ bpftool iter pin ./bpf_iter_ipv6_route.o /sys/fs/bpf/my_route

	And then print out the results using the following command:

	::

	$ cat /sys/fs/bpf/my_route


	-------------------------------------------------------
	Implement Kernel Support for BPF Iterator Program Types
	-------------------------------------------------------

	To implement a BPF iterator in the kernel, the developer must make a one-time
	change to the following key data structure defined in the `bpf.h
	<https://git.kernel.org/pub/scm/linux/kernel/git/bpf/bpf-next.git/tree/include/linux/bpf.h>`_
	file.

	::

	struct bpf_iter_reg {
	const char *target;
	bpf_iter_attach_target_t attach_target;
	bpf_iter_detach_target_t detach_target;
	bpf_iter_show_fdinfo_t show_fdinfo;
	bpf_iter_fill_link_info_t fill_link_info;
	bpf_iter_get_func_proto_t get_func_proto;
	u32 ctx_arg_info_size;
	u32 feature;
	struct bpf_ctx_arg_aux ctx_arg_info[BPF_ITER_CTX_ARG_MAX];
	const struct bpf_iter_seq_info *seq_info;
	};

	After filling the data structure fields, call ``bpf_iter_reg_target()`` to
	register the iterator to the main BPF iterator subsystem.

	The following is the breakdown for each field in struct ``bpf_iter_reg``.

	.. list-table::
	:widths: 25 50
	:header-rows: 1

	* - Fields
	- Description
	* - target
	- Specifies the name of the BPF iterator. For example: ``bpf_map``,
	``bpf_map_elem``. The name should be different from other ``bpf_iter`` target names in the kernel.
	* - attach_target and detach_target
	- Allows for target specific ``link_create`` action since some targets
	may need special processing. Called during the user space link_create stage.
	* - show_fdinfo and fill_link_info
	- Called to fill target specific information when user tries to get link
	info associated with the iterator.
	* - get_func_proto
	- Permits a BPF iterator to access BPF helpers specific to the iterator.
	* - ctx_arg_info_size and ctx_arg_info
	- Specifies the verifier states for BPF program arguments associated with
	the bpf iterator.
	* - feature
	- Specifies certain action requests in the kernel BPF iterator
	infrastructure. Currently, only BPF_ITER_RESCHED is supported. This means
	that the kernel function cond_resched() is called to avoid other kernel
	subsystem (e.g., rcu) misbehaving.
	* - seq_info
	- Specifies the set of seq operations for the BPF iterator and helpers to
	initialize/free the private data for the corresponding ``seq_file``.

	`Click here
	<https://lore.kernel.org/bpf/20210212183107.50963-2-songliubraving@fb.com/>`_
	to see an implementation of the ``task_vma`` BPF iterator in the kernel.

	---------------------------------
	Parameterizing BPF Task Iterators
	---------------------------------

	By default, BPF iterators walk through all the objects of the specified types
	(processes, cgroups, maps, etc.) across the entire system to read relevant
	kernel data. But often, there are cases where we only care about a much smaller
	subset of iterable kernel objects, such as only iterating tasks within a
	specific process. Therefore, BPF iterator programs support filtering out objects
	from iteration by allowing user space to configure the iterator program when it
	is attached.

	--------------------------
	BPF Task Iterator Program
	--------------------------

	The following code is a BPF iterator program to print files and task information
	through the ``seq_file`` of the iterator. It is a standard BPF iterator program
	that visits every file of an iterator. We will use this BPF program in our
	example later.

	::

	#include <vmlinux.h>
	#include <bpf/bpf_helpers.h>

	char _license[] SEC("license") = "GPL";

	SEC("iter/task_file")
	int dump_task_file(struct bpf_iter__task_file *ctx)
	{
	struct seq_file *seq = ctx->meta->seq;
	struct task_struct *task = ctx->task;
	struct file *file = ctx->file;
	__u32 fd = ctx->fd;
	if (task == NULL \|\| file == NULL)
	return 0;
	if (ctx->meta->seq_num == 0) {
	BPF_SEQ_PRINTF(seq, " tgid pid fd file\n");
	}
	BPF_SEQ_PRINTF(seq, "%8d %8d %8d %lx\n", task->tgid, task->pid, fd,
	(long)file->f_op);
	return 0;
	}

	----------------------------------------
	Creating a File Iterator with Parameters
	----------------------------------------

	Now, let us look at how to create an iterator that includes only files of a
	process.

	First, fill the ``bpf_iter_attach_opts`` struct as shown below:

	::

	LIBBPF_OPTS(bpf_iter_attach_opts, opts);
	union bpf_iter_link_info linfo;
	memset(&linfo, 0, sizeof(linfo));
	linfo.task.pid = getpid();
	opts.link_info = &linfo;
	opts.link_info_len = sizeof(linfo);

	``linfo.task.pid``, if it is non-zero, directs the kernel to create an iterator
	that only includes opened files for the process with the specified ``pid``. In
	this example, we will only be iterating files for our process. If
	``linfo.task.pid`` is zero, the iterator will visit every opened file of every
	process. Similarly, ``linfo.task.tid`` directs the kernel to create an iterator
	that visits opened files of a specific thread, not a process. In this example,
	``linfo.task.tid`` is different from ``linfo.task.pid`` only if the thread has a
	separate file descriptor table. In most circumstances, all process threads share
	a single file descriptor table.

	Now, in the userspace program, pass the pointer of struct to the
	``bpf_program__attach_iter()``.

	::

	link = bpf_program__attach_iter(prog, &opts); iter_fd =
	bpf_iter_create(bpf_link__fd(link));

	If both tid and pid are zero, an iterator created from this struct
	``bpf_iter_attach_opts`` will include every opened file of every task in the
	system (in the namespace, actually.) It is the same as passing a NULL as the
	second argument to ``bpf_program__attach_iter()``.

	The whole program looks like the following code:

	::

	#include <stdio.h>
	#include <unistd.h>
	#include <bpf/bpf.h>
	#include <bpf/libbpf.h>
	#include "bpf_iter_task_ex.skel.h"

	static int do_read_opts(struct bpf_program prog, struct bpf_iter_attach_opts opts)
	{
	struct bpf_link *link;
	char buf[16] = {};
	int iter_fd = -1, len;
	int ret = 0;

	link = bpf_program__attach_iter(prog, opts);
	if (!link) {
	fprintf(stderr, "bpf_program__attach_iter() fails\n");
	return -1;
	}
	iter_fd = bpf_iter_create(bpf_link__fd(link));
	if (iter_fd < 0) {
	fprintf(stderr, "bpf_iter_create() fails\n");
	ret = -1;
	goto free_link;
	}
	/* not check contents, but ensure read() ends without error */
	while ((len = read(iter_fd, buf, sizeof(buf) - 1)) > 0) {
	buf[len] = 0;
	printf("%s", buf);
	}
	printf("\n");
	free_link:
	if (iter_fd >= 0)
	close(iter_fd);
	bpf_link__destroy(link);
	return 0;
	}

	static void test_task_file(void)
	{
	LIBBPF_OPTS(bpf_iter_attach_opts, opts);
	struct bpf_iter_task_ex *skel;
	union bpf_iter_link_info linfo;
	skel = bpf_iter_task_ex__open_and_load();
	if (skel == NULL)
	return;
	memset(&linfo, 0, sizeof(linfo));
	linfo.task.pid = getpid();
	opts.link_info = &linfo;
	opts.link_info_len = sizeof(linfo);
	printf("PID %d\n", getpid());
	do_read_opts(skel->progs.dump_task_file, &opts);
	bpf_iter_task_ex__destroy(skel);
	}

	int main(int argc, const char * const * argv)
	{
	test_task_file();
	return 0;
	}

	The following lines are the output of the program.
	::

	PID 1859

	tgid pid fd file
	1859 1859 0 ffffffff82270aa0
	1859 1859 1 ffffffff82270aa0
	1859 1859 2 ffffffff82270aa0
	1859 1859 3 ffffffff82272980
	1859 1859 4 ffffffff8225e120
	1859 1859 5 ffffffff82255120
	1859 1859 6 ffffffff82254f00
	1859 1859 7 ffffffff82254d80
	1859 1859 8 ffffffff8225abe0

	------------------
	Without Parameters
	------------------

	Let us look at how a BPF iterator without parameters skips files of other
	processes in the system. In this case, the BPF program has to check the pid or
	the tid of tasks, or it will receive every opened file in the system (in the
	current pid namespace, actually). So, we usually add a global variable in the
	BPF program to pass a pid to the BPF program.

	The BPF program would look like the following block.

	::

	......
	int target_pid = 0;

	SEC("iter/task_file")
	int dump_task_file(struct bpf_iter__task_file *ctx)
	{
	......
	if (task->tgid != target_pid) /* Check task->pid instead to check thread IDs */
	return 0;
	BPF_SEQ_PRINTF(seq, "%8d %8d %8d %lx\n", task->tgid, task->pid, fd,
	(long)file->f_op);
	return 0;
	}

	The user space program would look like the following block:

	::

	......
	static void test_task_file(void)
	{
	......
	skel = bpf_iter_task_ex__open_and_load();
	if (skel == NULL)
	return;
	skel->bss->target_pid = getpid(); /* process ID. For thread id, use gettid() */
	memset(&linfo, 0, sizeof(linfo));
	linfo.task.pid = getpid();
	opts.link_info = &linfo;
	opts.link_info_len = sizeof(linfo);
	......
	}

	``target_pid`` is a global variable in the BPF program. The user space program
	should initialize the variable with a process ID to skip opened files of other
	processes in the BPF program. When you parametrize a BPF iterator, the iterator
	calls the BPF program fewer times which can save significant resources.

	---------------------------
	Parametrizing VMA Iterators
	---------------------------

	By default, a BPF VMA iterator includes every VMA in every process. However,
	you can still specify a process or a thread to include only its VMAs. Unlike
	files, a thread can not have a separate address space (since Linux 2.6.0-test6).
	Here, using tid makes no difference from using pid.

	----------------------------
	Parametrizing Task Iterators
	----------------------------

	A BPF task iterator with pid includes all tasks (threads) of a process. The
	BPF program receives these tasks one after another. You can specify a BPF task
	iterator with tid parameter to include only the tasks that match the given
	tid.