Hook points
Tetragon can hook into the kernel using kprobes
and tracepoints
, as well as in user-space
programs using uprobes
. Users can configure these hook points using the correspodning sections of
the TracingPolicy
specification (.spec
). These hook points include arguments and return values
that can be specified using the args
and returnArg
fields as detailed in the following sections.
Kprobes
Kprobes enables you to dynamically hook into any kernel function and execute BPF code. Because kernel functions might change across versions, kprobes are highly tied to your kernel version and, thus, might not be portable across different kernels.
Conveniently, you can list all kernel symbols reading the /proc/kallsyms
file. For example to search for the write
syscall kernel function, you can
execute sudo grep sys_write /proc/kallsyms
, the output should be similar to
this, minus the architecture specific prefixes.
ffffdeb14ea712e0 T __arm64_sys_writev
ffffdeb14ea73010 T ksys_write
ffffdeb14ea73140 T __arm64_sys_write
ffffdeb14eb5a460 t proc_sys_write
ffffdeb15092a700 d _eil_addr___arm64_sys_writev
ffffdeb15092a740 d _eil_addr___arm64_sys_write
You can see that the exact name of the symbol for the write syscall on our
kernel version is __arm64_sys_write
. Note that on x86_64
, the prefix would
be __x64_
instead of __arm64_
.
Kernel symbols contain an architecture specific prefix when they refer to syscall symbols. To write portable tracing policies, i.e. policies that can run on multiple architectures, just use the symbol name without the prefix.
For example, instead of writing call: "__arm64_sys_write"
or call: "__x64_sys_write"
, just write call: "sys_write"
, Tetragon will adapt and add
the correct prefix based on the architecture of the underlying machine. Note
that the event generated as output currently includes the prefix.
In our example, we will explore a kprobe
hooking into the
fd_install
kernel function. The fd_install
kernel function is called each time a file
descriptor is installed into the file descriptor table of a process, typically
referenced within system calls like open
or openat
. Hooking fd_install
has its benefits and limitations, which are out of the scope of this guide.
spec:
kprobes:
- call: "fd_install"
syscall: false
syscall
field, specific to a kprobe
spec, with default value
false
, that indicates whether Tetragon will hook a syscall or just a regular
kernel function. Tetragon needs this information because syscall and kernel
function use a different ABI.
Kprobes calls can be defined independently in different policies, or together in the same Policy. For example, we can define trace multiple kprobes under the same tracing policy:
spec:
kprobes:
- call: "sys_read"
syscall: true
# [...]
- call: "sys_write"
syscall: true
# [...]
Tracepoints
Tracepoints are statically defined in the kernel and have the advantage of being stable across kernel versions and thus more portable than kprobes.
To see the list of tracepoints available on your kernel, you can list them
using sudo ls /sys/kernel/debug/tracing/events
, the output should be similar
to this.
alarmtimer ext4 iommu page_pool sock
avc fib ipi pagemap spi
block fib6 irq percpu swiotlb
bpf_test_run filelock jbd2 power sync_trace
bpf_trace filemap kmem printk syscalls
bridge fs_dax kvm pwm task
btrfs ftrace libata qdisc tcp
cfg80211 gpio lock ras tegra_apb_dma
cgroup hda mctp raw_syscalls thermal
clk hda_controller mdio rcu thermal_power_allocator
cma hda_intel migrate regmap thermal_pressure
compaction header_event mmap regulator thp
cpuhp header_page mmap_lock rpm timer
cros_ec huge_memory mmc rpmh tlb
dev hwmon module rseq tls
devfreq i2c mptcp rtc udp
devlink i2c_slave napi sched vmscan
dma_fence initcall neigh scmi wbt
drm interconnect net scsi workqueue
emulation io_uring netlink signal writeback
enable iocost oom skb xdp
error_report iomap page_isolation smbus xhci-hcd
You can then choose the subsystem that you want to trace, and look the
tracepoint you want to use and its format. For example, if we choose the
netif_receive_skb
tracepoints from the net
subsystem, we can read its
format with sudo cat /sys/kernel/debug/tracing/events/net/netif_receive_skb/format
,
the output should be similar to the following.
name: netif_receive_skb
ID: 1398
format:
field:unsigned short common_type; offset:0; size:2; signed:0;
field:unsigned char common_flags; offset:2; size:1; signed:0;
field:unsigned char common_preempt_count; offset:3; size:1; signed:0;
field:int common_pid; offset:4; size:4; signed:1;
field:void * skbaddr; offset:8; size:8; signed:0;
field:unsigned int len; offset:16; size:4; signed:0;
field:__data_loc char[] name; offset:20; size:4; signed:0;
print fmt: "dev=%s skbaddr=%px len=%u", __get_str(name), REC->skbaddr, REC->len
Similarly to kprobes, tracepoints can also hook into system calls. For more
details, see the raw_syscalls
and syscalls
subysystems.
An example of tracepoints TracingPolicy
could be the following, observing all
syscalls and getting the syscall ID from the argument at index 4:
apiVersion: cilium.io/v1alpha1
kind: TracingPolicy
metadata:
name: "raw-syscalls"
spec:
tracepoints:
- subsystem: "raw_syscalls"
event: "sys_enter"
args:
- index: 4
type: "int64"
Uprobes
Uprobes are similar to kprobes, but they allow you to dynamically hook into any user-space function and execute BPF code. Uprobes are also tied to the binary version of the user-space program, so they may not be portable across different versions or architectures.
To use uprobes, you need to specify the path to the executable or library file,
and the symbol of the function you want to probe. You can use tools like
objdump
, nm
, or readelf
to find the symbol of a function in a binary
file. For example, to find the readline symbol in /bin/bash
using nm
, you
can run:
nm -D /bin/bash | grep readline
The output should look similar to this, with a few lines redacted:
[...]
000000000009f2b0 T pcomp_set_readline_variables
0000000000097e40 T posix_readline_initialize
00000000000d5690 T readline
00000000000d52f0 T readline_internal_char
00000000000d42d0 T readline_internal_setup
[...]
You can see in the nm
output: first the symbol value, then the symbol type,
for the readline
symbol T
meaning that this symbol is in the text (code)
section of the binary, and finally the symbol name. This confirms that the
readline
symbol is present in the /bin/bash
binary and might be a function
name that we can hook with a uprobe.
You can define multiple uprobes in the same policy, or in different policies. You can also combine uprobes with kprobes and tracepoints to get a comprehensive view of the system behavior.
Here is an example of a policy that defines an uprobe for the readline function in the bash executable, and applies it to all processes that use the bash binary:
apiVersion: cilium.io/v1alpha1
kind: TracingPolicy
metadata:
name: "example-uprobe"
spec:
uprobes:
- path: "/bin/bash"
symbols:
- "readline"
This example shows how to use uprobes to hook into the readline function running in all the bash shells.
LSM BPF
LSM BPF programs allow runtime instrumentation of the LSM hooks by privileged users to implement system-wide MAC (Mandatory Access Control) and Audit policies using eBPF.
List of LSM hooks which can be instrumented can be found in security/security.c
.
To verify if BPF LSM is available use the following command:
cat /boot/config-$(uname -r) | grep BPF_LSM
The output should be similar to this if BPF LSM is supported:
CONFIG_BPF_LSM=y
Then, if provided above conditions are met, use this command to check if BPF LSM is enabled:
cat /sys/kernel/security/lsm
The output might look like this:
bpf,lockdown,integrity,apparmor
If the output includes the bpf
, than BPF LSM is enabled. Otherwise, you can modify /etc/default/grub
:
GRUB_CMDLINE_LINUX="lsm=lockdown,integrity,apparmor,bpf"
Then, update the grub configuration and restart the system.
The provided example of LSM BPF TracingPolicy
monitors access to files
/etc/passwd
and /etc/shadow
with /usr/bin/cat
executable.
apiVersion: cilium.io/v1alpha1
kind: TracingPolicy
metadata:
name: "lsm-file-open"
spec:
lsmhooks:
- hook: "file_open"
args:
- index: 0
type: "file"
selectors:
- matchBinaries:
- operator: "In"
values:
- "/usr/bin/cat"
matchArgs:
- index: 0
operator: "Equal"
values:
- "/etc/passwd"
- "/etc/shadow"
Arguments
Kprobes, uprobes and tracepoints all share a needed arguments fields called args
. It is a list of
arguments to include in the trace output. Tetragon’s BPF code requires
information about the types of arguments to properly read, print and
filter on its arguments. This information needs to be provided by the user under the
args
section. For the available
types,
check the TracingPolicy
CRD.
Following our example, here is the part that defines the arguments:
args:
- index: 0
type: "int"
- index: 1
type: "file"
Each argument can optionally include a ’label’ parameter, which will be included in the output. This can be used to annotate the arguments to help with understanding and processing the output. As an example, here is the same definition, with an appropriate label on the int argument:
args:
- index: 0
type: "int"
label: "FD"
- index: 1
type: "file"
To properly read and hook onto the fd_install(unsigned int fd, struct file *file)
function, the YAML snippet above tells the BPF code that the first
argument is an int
and the second argument is a file
, which is the
struct file
of the kernel. In this way, the BPF code and its printer can properly collect
and print the arguments.
These types are sorted by the index
field, where you can specify the order.
The indexing starts with 0. So, index: 0
means, this is going to be the first
argument of the function, index: 1
means this is going to be the second
argument of the function, etc.
Note that for some args types, char_buf
and char_iovec
, there are
additional fields named returnCopy
and sizeArgIndex
available:
returnCopy
indicates that the corresponding argument should be read later (when the kretprobe for the symbol is triggered) because it might not be populated when the kprobe is triggered at the entrance of the function. For example, a buffer supplied toread(2)
won’t have content until kretprobe is triggered.sizeArgIndex
indicates the (1-based, see warning below) index of the arguments that represents the size of thechar_buf
oriovec
. For example, forwrite(2)
, the third argument,size_t count
is the number ofchar
element that we can read from theconst void *buf
pointer from the second argument. Similarly, if we would like to capture the__x64_sys_writev(long, iovec *, vlen)
syscall, theniovec
has a size ofvlen
, which is going to be the third argument.
sizeArgIndex
is inconsistent at the moment and does not take the index, but
the number of the index (or index + 1). So if the size is the third argument,
index 2, the value should be 3.
These flags can be combined, see the example below.
- call: "sys_write"
syscall: true
args:
- index: 0
type: "int"
- index: 1
type: "char_buf"
returnCopy: true
sizeArgIndex: 3
- index: 2
type: "size_t"
Note that you can specify which arguments you would like to print from a
specific syscall. For example if you don’t care about the file descriptor,
which is the first int
argument with index: 0
and just want the char_buf
,
what is written, then you can leave this section out and just define:
args:
- index: 1
type: "char_buf"
returnCopy: true
sizeArgIndex: 3
- index: 2
type: "size_t"
This tells the printer to skip printing the int
arg because it’s not useful.
For char_buf
type up to the 4096 bytes are stored. Data with bigger size are
cut and returned as truncated bytes.
You can specify maxData
flag for char_buf
type to read maximum possible data
(currently 327360 bytes), like:
args:
- index: 1
type: "char_buf"
maxData: true
sizeArgIndex: 3
- index: 2
type: "size_t"
This field is only used for char_buff
data. When this value is false (default),
the bpf program will fetch at most 4096 bytes. In later kernels (>=5.4) tetragon
supports fetching up to 327360 bytes if this flag is turned on.
The maxData
flag does not work with returnCopy
flag at the moment, so it’s
usable only for syscalls/functions that do not require return probe to read the
data.
Return values
A TracingPolicy
spec can specify that the return value should be reported in
the tracing output. To do this, the return
parameter of the call needs to be
set to true
, and the returnArg
parameter needs to be set to specify the
type
of the return argument. For example:
- call: "sk_alloc"
syscall: false
return: true
args:
- index: 1
type: int
label: "family"
returnArg:
type: sock
In this case, the sk_alloc
hook is specified to return a value of type sock
(a pointer to a struct sock
). Whenever the sk_alloc
hook is hit, not only
will it report the family
parameter in index 1, it will also report the socket
that was created.
Return values for socket tracking
A unique feature of a sock
being returned from a hook such as sk_alloc
is that
the socket it refers to can be tracked. Most networking hooks in the network stack
are run in a context that is not that of the process that owns the socket for which
the actions relate; this is because networking happens asynchronously and not
entirely in-line with the process. The sk_alloc
hook does, however, occur in the
context of the process, such that the task, the PID, and the TGID are of the process
that requested that the socket was created.
Specifying socket tracking tells Tetragon to store a mapping between the socket
and the process’ PID and TGID; and to use that mapping when it sees the socket in a
sock
argument in another hook to replace the PID and TGID of the context with the
process that actually owns the socket. This can be done by adding a returnArgAction
to the call. Available actions are TrackSock
and UntrackSock
.
See TrackSock
and UntrackSock
.
- call: "sk_alloc"
syscall: false
return: true
args:
- index: 1
type: int
label: "family"
returnArg:
type: sock
returnArgAction: TrackSock
Socket tracking is only available on kernels >=5.3.
Lists
It’s possible to define list of functions and use it in the kprobe’s call
field.
Following example traces all sys_dup[23]
syscalls.
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "sys_dup2"
- "sys_dup3"
kprobes:
- call: "list:dups"
It is basically a shortcut for following policy:
spec:
kprobes:
- call: "sys_dup"
syscall: true
- call: "sys_dup2"
syscall: true
- call: "sys_dup3"
syscall: true
As shown in subsequent examples, its main benefit is allowing a single definition for calls that have the same filters.
The list is defined under lists
field with arbitrary values for name
and values
fields.
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "sys_dup2"
- "sys_dup3"
...
It’s possible to define multiple lists.
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "sys_dup2"
- "sys_dup3"
name: "another"
- "sys_open"
- "sys_close"
Syscalls specified with sys_
prefix are translated to their 64 bit equivalent function names.
It’s possible to specify 32 bit syscall by using its full function name that
includes specific architecture native prefix (like __ia32_
for x86
):
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "__ia32_sys_dup"
name: "another"
- "sys_open"
- "sys_close"
Specific list can be referenced in kprobe’s call
field with "list:NAME"
value.
spec:
lists:
- name: "dups"
...
kprobes:
- call: "list:dups"
The kprobe definition creates a kprobe for each item in the list and shares the rest of the config specified for kprobe.
List can also specify type
field that implies extra checks on the values (like for syscall
type)
or denote that the list is generated automatically (see below).
User must specify syscall
type for list with syscall functions. Also syscall
functions
can’t be mixed with regular functions in the list.
The additional selector configuration is shared with all functions in the list. In following example we create 3 kprobes that share the same pid filter.
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "sys_dup2"
- "sys_dup3"
kprobes:
- call: "list:dups"
selectors:
- matchPIDs:
- operator: In
followForks: true
isNamespacePID: false
values:
- 12345
It’s possible to use argument filter together with the list
.
It’s important to understand that the argument will be retrieved by using the specified argument type for all the functions in the list.
Following example adds argument filter for first argument on all functions in dups list to match value 9999.
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "sys_dup2"
- "sys_dup3"
kprobes:
- call: "list:dups"
args:
- index: 0
type: int
selectors:
- matchArgs:
- index: 0
operator: "Equal"
values:
- 9999
There are two additional special types of generated lists.
The generated_syscalls
type of list that generates list with all possible
syscalls on the system.
Following example traces all syscalls for /usr/bin/kill
binary.
spec:
lists:
- name: "all-syscalls"
type: "generated_syscalls"
kprobes:
- call: "list:all-syscalls"
selectors:
- matchBinaries:
- operator: "In"
values:
- "/usr/bin/kill"
The generated_ftrace
type of list that generates functions from ftrace available_filter_functions
file with specified filter. The filter is specified with pattern
field and expects regular expression.
Following example traces all kernel ksys_*
functions for /usr/bin/kill
binary.
spec:
lists:
- name: "ksys"
type: "generated_ftrace"
pattern: "^ksys_*"
kprobes:
- call: "list:ksys"
selectors:
- matchBinaries:
- operator: "In"
values:
- "/usr/bin/kill"
Note that if syscall list is used in selector with InMap operator, the argument type needs to be syscall64
, like.
spec:
lists:
- name: "dups"
type: "syscalls"
values:
- "sys_dup"
- "__ia32_sys_dup"
tracepoints:
- subsystem: "raw_syscalls"
event: "sys_enter"
args:
- index: 4
type: "syscall64"
selectors:
- matchArgs:
- index: 0
operator: "InMap"
values:
- "list:dups"