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This is a followup for [1], adds an overview for the register liveness tracking, covers the following points: - why register liveness tracking is useful; - how register parentage chains are constructed; - how liveness marks are applied using the parentage chains. [1] https://lore.kernel.org/bpf/CAADnVQKs2i1iuZ5SUGuJtxWVfGYR9kDgYKhq3rNV+kBLQCu7rA@mail.gmail.com/ Signed-off-by: Eduard Zingerman <eddyz87@gmail.com> Reviewed-by: Edward Cree <ecree.xilinx@gmail.com> Link: https://lore.kernel.org/r/20230202125713.821931-2-eddyz87@gmail.com Signed-off-by: Alexei Starovoitov <ast@kernel.org>
825 lines
31 KiB
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825 lines
31 KiB
ReStructuredText
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=============
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eBPF verifier
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=============
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The safety of the eBPF program is determined in two steps.
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First step does DAG check to disallow loops and other CFG validation.
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In particular it will detect programs that have unreachable instructions.
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(though classic BPF checker allows them)
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Second step starts from the first insn and descends all possible paths.
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It simulates execution of every insn and observes the state change of
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registers and stack.
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At the start of the program the register R1 contains a pointer to context
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and has type PTR_TO_CTX.
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If verifier sees an insn that does R2=R1, then R2 has now type
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PTR_TO_CTX as well and can be used on the right hand side of expression.
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If R1=PTR_TO_CTX and insn is R2=R1+R1, then R2=SCALAR_VALUE,
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since addition of two valid pointers makes invalid pointer.
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(In 'secure' mode verifier will reject any type of pointer arithmetic to make
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sure that kernel addresses don't leak to unprivileged users)
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If register was never written to, it's not readable::
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bpf_mov R0 = R2
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bpf_exit
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will be rejected, since R2 is unreadable at the start of the program.
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After kernel function call, R1-R5 are reset to unreadable and
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R0 has a return type of the function.
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Since R6-R9 are callee saved, their state is preserved across the call.
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::
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bpf_mov R6 = 1
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bpf_call foo
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bpf_mov R0 = R6
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bpf_exit
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is a correct program. If there was R1 instead of R6, it would have
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been rejected.
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load/store instructions are allowed only with registers of valid types, which
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are PTR_TO_CTX, PTR_TO_MAP, PTR_TO_STACK. They are bounds and alignment checked.
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For example::
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bpf_mov R1 = 1
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bpf_mov R2 = 2
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bpf_xadd *(u32 *)(R1 + 3) += R2
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bpf_exit
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will be rejected, since R1 doesn't have a valid pointer type at the time of
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execution of instruction bpf_xadd.
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At the start R1 type is PTR_TO_CTX (a pointer to generic ``struct bpf_context``)
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A callback is used to customize verifier to restrict eBPF program access to only
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certain fields within ctx structure with specified size and alignment.
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For example, the following insn::
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bpf_ld R0 = *(u32 *)(R6 + 8)
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intends to load a word from address R6 + 8 and store it into R0
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If R6=PTR_TO_CTX, via is_valid_access() callback the verifier will know
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that offset 8 of size 4 bytes can be accessed for reading, otherwise
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the verifier will reject the program.
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If R6=PTR_TO_STACK, then access should be aligned and be within
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stack bounds, which are [-MAX_BPF_STACK, 0). In this example offset is 8,
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so it will fail verification, since it's out of bounds.
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The verifier will allow eBPF program to read data from stack only after
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it wrote into it.
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Classic BPF verifier does similar check with M[0-15] memory slots.
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For example::
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bpf_ld R0 = *(u32 *)(R10 - 4)
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bpf_exit
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is invalid program.
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Though R10 is correct read-only register and has type PTR_TO_STACK
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and R10 - 4 is within stack bounds, there were no stores into that location.
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Pointer register spill/fill is tracked as well, since four (R6-R9)
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callee saved registers may not be enough for some programs.
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Allowed function calls are customized with bpf_verifier_ops->get_func_proto()
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The eBPF verifier will check that registers match argument constraints.
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After the call register R0 will be set to return type of the function.
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Function calls is a main mechanism to extend functionality of eBPF programs.
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Socket filters may let programs to call one set of functions, whereas tracing
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filters may allow completely different set.
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If a function made accessible to eBPF program, it needs to be thought through
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from safety point of view. The verifier will guarantee that the function is
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called with valid arguments.
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seccomp vs socket filters have different security restrictions for classic BPF.
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Seccomp solves this by two stage verifier: classic BPF verifier is followed
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by seccomp verifier. In case of eBPF one configurable verifier is shared for
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all use cases.
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See details of eBPF verifier in kernel/bpf/verifier.c
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Register value tracking
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=======================
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In order to determine the safety of an eBPF program, the verifier must track
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the range of possible values in each register and also in each stack slot.
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This is done with ``struct bpf_reg_state``, defined in include/linux/
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bpf_verifier.h, which unifies tracking of scalar and pointer values. Each
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register state has a type, which is either NOT_INIT (the register has not been
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written to), SCALAR_VALUE (some value which is not usable as a pointer), or a
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pointer type. The types of pointers describe their base, as follows:
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PTR_TO_CTX
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Pointer to bpf_context.
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CONST_PTR_TO_MAP
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Pointer to struct bpf_map. "Const" because arithmetic
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on these pointers is forbidden.
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PTR_TO_MAP_VALUE
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Pointer to the value stored in a map element.
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PTR_TO_MAP_VALUE_OR_NULL
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Either a pointer to a map value, or NULL; map accesses
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(see maps.rst) return this type, which becomes a
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PTR_TO_MAP_VALUE when checked != NULL. Arithmetic on
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these pointers is forbidden.
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PTR_TO_STACK
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Frame pointer.
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PTR_TO_PACKET
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skb->data.
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PTR_TO_PACKET_END
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skb->data + headlen; arithmetic forbidden.
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PTR_TO_SOCKET
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Pointer to struct bpf_sock_ops, implicitly refcounted.
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PTR_TO_SOCKET_OR_NULL
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Either a pointer to a socket, or NULL; socket lookup
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returns this type, which becomes a PTR_TO_SOCKET when
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checked != NULL. PTR_TO_SOCKET is reference-counted,
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so programs must release the reference through the
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socket release function before the end of the program.
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Arithmetic on these pointers is forbidden.
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However, a pointer may be offset from this base (as a result of pointer
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arithmetic), and this is tracked in two parts: the 'fixed offset' and 'variable
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offset'. The former is used when an exactly-known value (e.g. an immediate
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operand) is added to a pointer, while the latter is used for values which are
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not exactly known. The variable offset is also used in SCALAR_VALUEs, to track
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the range of possible values in the register.
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The verifier's knowledge about the variable offset consists of:
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* minimum and maximum values as unsigned
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* minimum and maximum values as signed
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* knowledge of the values of individual bits, in the form of a 'tnum': a u64
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'mask' and a u64 'value'. 1s in the mask represent bits whose value is unknown;
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1s in the value represent bits known to be 1. Bits known to be 0 have 0 in both
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mask and value; no bit should ever be 1 in both. For example, if a byte is read
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into a register from memory, the register's top 56 bits are known zero, while
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the low 8 are unknown - which is represented as the tnum (0x0; 0xff). If we
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then OR this with 0x40, we get (0x40; 0xbf), then if we add 1 we get (0x0;
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0x1ff), because of potential carries.
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Besides arithmetic, the register state can also be updated by conditional
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branches. For instance, if a SCALAR_VALUE is compared > 8, in the 'true' branch
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it will have a umin_value (unsigned minimum value) of 9, whereas in the 'false'
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branch it will have a umax_value of 8. A signed compare (with BPF_JSGT or
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BPF_JSGE) would instead update the signed minimum/maximum values. Information
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from the signed and unsigned bounds can be combined; for instance if a value is
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first tested < 8 and then tested s> 4, the verifier will conclude that the value
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is also > 4 and s< 8, since the bounds prevent crossing the sign boundary.
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PTR_TO_PACKETs with a variable offset part have an 'id', which is common to all
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pointers sharing that same variable offset. This is important for packet range
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checks: after adding a variable to a packet pointer register A, if you then copy
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it to another register B and then add a constant 4 to A, both registers will
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share the same 'id' but the A will have a fixed offset of +4. Then if A is
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bounds-checked and found to be less than a PTR_TO_PACKET_END, the register B is
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now known to have a safe range of at least 4 bytes. See 'Direct packet access',
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below, for more on PTR_TO_PACKET ranges.
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The 'id' field is also used on PTR_TO_MAP_VALUE_OR_NULL, common to all copies of
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the pointer returned from a map lookup. This means that when one copy is
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checked and found to be non-NULL, all copies can become PTR_TO_MAP_VALUEs.
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As well as range-checking, the tracked information is also used for enforcing
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alignment of pointer accesses. For instance, on most systems the packet pointer
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is 2 bytes after a 4-byte alignment. If a program adds 14 bytes to that to jump
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over the Ethernet header, then reads IHL and adds (IHL * 4), the resulting
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pointer will have a variable offset known to be 4n+2 for some n, so adding the 2
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bytes (NET_IP_ALIGN) gives a 4-byte alignment and so word-sized accesses through
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that pointer are safe.
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The 'id' field is also used on PTR_TO_SOCKET and PTR_TO_SOCKET_OR_NULL, common
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to all copies of the pointer returned from a socket lookup. This has similar
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behaviour to the handling for PTR_TO_MAP_VALUE_OR_NULL->PTR_TO_MAP_VALUE, but
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it also handles reference tracking for the pointer. PTR_TO_SOCKET implicitly
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represents a reference to the corresponding ``struct sock``. To ensure that the
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reference is not leaked, it is imperative to NULL-check the reference and in
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the non-NULL case, and pass the valid reference to the socket release function.
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Direct packet access
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====================
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In cls_bpf and act_bpf programs the verifier allows direct access to the packet
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data via skb->data and skb->data_end pointers.
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Ex::
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1: r4 = *(u32 *)(r1 +80) /* load skb->data_end */
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2: r3 = *(u32 *)(r1 +76) /* load skb->data */
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3: r5 = r3
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4: r5 += 14
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5: if r5 > r4 goto pc+16
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R1=ctx R3=pkt(id=0,off=0,r=14) R4=pkt_end R5=pkt(id=0,off=14,r=14) R10=fp
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6: r0 = *(u16 *)(r3 +12) /* access 12 and 13 bytes of the packet */
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this 2byte load from the packet is safe to do, since the program author
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did check ``if (skb->data + 14 > skb->data_end) goto err`` at insn #5 which
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means that in the fall-through case the register R3 (which points to skb->data)
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has at least 14 directly accessible bytes. The verifier marks it
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as R3=pkt(id=0,off=0,r=14).
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id=0 means that no additional variables were added to the register.
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off=0 means that no additional constants were added.
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r=14 is the range of safe access which means that bytes [R3, R3 + 14) are ok.
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Note that R5 is marked as R5=pkt(id=0,off=14,r=14). It also points
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to the packet data, but constant 14 was added to the register, so
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it now points to ``skb->data + 14`` and accessible range is [R5, R5 + 14 - 14)
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which is zero bytes.
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More complex packet access may look like::
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R0=inv1 R1=ctx R3=pkt(id=0,off=0,r=14) R4=pkt_end R5=pkt(id=0,off=14,r=14) R10=fp
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6: r0 = *(u8 *)(r3 +7) /* load 7th byte from the packet */
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7: r4 = *(u8 *)(r3 +12)
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8: r4 *= 14
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9: r3 = *(u32 *)(r1 +76) /* load skb->data */
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10: r3 += r4
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11: r2 = r1
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12: r2 <<= 48
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13: r2 >>= 48
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14: r3 += r2
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15: r2 = r3
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16: r2 += 8
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17: r1 = *(u32 *)(r1 +80) /* load skb->data_end */
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18: if r2 > r1 goto pc+2
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R0=inv(id=0,umax_value=255,var_off=(0x0; 0xff)) R1=pkt_end R2=pkt(id=2,off=8,r=8) R3=pkt(id=2,off=0,r=8) R4=inv(id=0,umax_value=3570,var_off=(0x0; 0xfffe)) R5=pkt(id=0,off=14,r=14) R10=fp
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19: r1 = *(u8 *)(r3 +4)
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The state of the register R3 is R3=pkt(id=2,off=0,r=8)
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id=2 means that two ``r3 += rX`` instructions were seen, so r3 points to some
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offset within a packet and since the program author did
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``if (r3 + 8 > r1) goto err`` at insn #18, the safe range is [R3, R3 + 8).
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The verifier only allows 'add'/'sub' operations on packet registers. Any other
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operation will set the register state to 'SCALAR_VALUE' and it won't be
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available for direct packet access.
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Operation ``r3 += rX`` may overflow and become less than original skb->data,
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therefore the verifier has to prevent that. So when it sees ``r3 += rX``
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instruction and rX is more than 16-bit value, any subsequent bounds-check of r3
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against skb->data_end will not give us 'range' information, so attempts to read
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through the pointer will give "invalid access to packet" error.
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Ex. after insn ``r4 = *(u8 *)(r3 +12)`` (insn #7 above) the state of r4 is
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R4=inv(id=0,umax_value=255,var_off=(0x0; 0xff)) which means that upper 56 bits
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of the register are guaranteed to be zero, and nothing is known about the lower
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8 bits. After insn ``r4 *= 14`` the state becomes
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R4=inv(id=0,umax_value=3570,var_off=(0x0; 0xfffe)), since multiplying an 8-bit
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value by constant 14 will keep upper 52 bits as zero, also the least significant
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bit will be zero as 14 is even. Similarly ``r2 >>= 48`` will make
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R2=inv(id=0,umax_value=65535,var_off=(0x0; 0xffff)), since the shift is not sign
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extending. This logic is implemented in adjust_reg_min_max_vals() function,
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which calls adjust_ptr_min_max_vals() for adding pointer to scalar (or vice
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versa) and adjust_scalar_min_max_vals() for operations on two scalars.
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The end result is that bpf program author can access packet directly
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using normal C code as::
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void *data = (void *)(long)skb->data;
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void *data_end = (void *)(long)skb->data_end;
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struct eth_hdr *eth = data;
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struct iphdr *iph = data + sizeof(*eth);
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struct udphdr *udp = data + sizeof(*eth) + sizeof(*iph);
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if (data + sizeof(*eth) + sizeof(*iph) + sizeof(*udp) > data_end)
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return 0;
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if (eth->h_proto != htons(ETH_P_IP))
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return 0;
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if (iph->protocol != IPPROTO_UDP || iph->ihl != 5)
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return 0;
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if (udp->dest == 53 || udp->source == 9)
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...;
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which makes such programs easier to write comparing to LD_ABS insn
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and significantly faster.
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Pruning
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=======
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The verifier does not actually walk all possible paths through the program. For
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each new branch to analyse, the verifier looks at all the states it's previously
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been in when at this instruction. If any of them contain the current state as a
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subset, the branch is 'pruned' - that is, the fact that the previous state was
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accepted implies the current state would be as well. For instance, if in the
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previous state, r1 held a packet-pointer, and in the current state, r1 holds a
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packet-pointer with a range as long or longer and at least as strict an
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alignment, then r1 is safe. Similarly, if r2 was NOT_INIT before then it can't
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have been used by any path from that point, so any value in r2 (including
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another NOT_INIT) is safe. The implementation is in the function regsafe().
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Pruning considers not only the registers but also the stack (and any spilled
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registers it may hold). They must all be safe for the branch to be pruned.
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This is implemented in states_equal().
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Some technical details about state pruning implementation could be found below.
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Register liveness tracking
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--------------------------
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In order to make state pruning effective, liveness state is tracked for each
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register and stack slot. The basic idea is to track which registers and stack
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slots are actually used during subseqeuent execution of the program, until
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program exit is reached. Registers and stack slots that were never used could be
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removed from the cached state thus making more states equivalent to a cached
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state. This could be illustrated by the following program::
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0: call bpf_get_prandom_u32()
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1: r1 = 0
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2: if r0 == 0 goto +1
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3: r0 = 1
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--- checkpoint ---
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4: r0 = r1
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5: exit
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Suppose that a state cache entry is created at instruction #4 (such entries are
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also called "checkpoints" in the text below). The verifier could reach the
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instruction with one of two possible register states:
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* r0 = 1, r1 = 0
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* r0 = 0, r1 = 0
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However, only the value of register ``r1`` is important to successfully finish
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verification. The goal of the liveness tracking algorithm is to spot this fact
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and figure out that both states are actually equivalent.
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Data structures
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~~~~~~~~~~~~~~~
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Liveness is tracked using the following data structures::
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enum bpf_reg_liveness {
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REG_LIVE_NONE = 0,
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REG_LIVE_READ32 = 0x1,
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REG_LIVE_READ64 = 0x2,
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REG_LIVE_READ = REG_LIVE_READ32 | REG_LIVE_READ64,
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REG_LIVE_WRITTEN = 0x4,
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REG_LIVE_DONE = 0x8,
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};
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struct bpf_reg_state {
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...
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struct bpf_reg_state *parent;
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...
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enum bpf_reg_liveness live;
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...
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};
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struct bpf_stack_state {
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struct bpf_reg_state spilled_ptr;
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...
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};
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struct bpf_func_state {
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struct bpf_reg_state regs[MAX_BPF_REG];
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...
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struct bpf_stack_state *stack;
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}
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struct bpf_verifier_state {
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struct bpf_func_state *frame[MAX_CALL_FRAMES];
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struct bpf_verifier_state *parent;
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...
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}
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* ``REG_LIVE_NONE`` is an initial value assigned to ``->live`` fields upon new
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verifier state creation;
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* ``REG_LIVE_WRITTEN`` means that the value of the register (or stack slot) is
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defined by some instruction verified between this verifier state's parent and
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verifier state itself;
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* ``REG_LIVE_READ{32,64}`` means that the value of the register (or stack slot)
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is read by a some child state of this verifier state;
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* ``REG_LIVE_DONE`` is a marker used by ``clean_verifier_state()`` to avoid
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processing same verifier state multiple times and for some sanity checks;
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* ``->live`` field values are formed by combining ``enum bpf_reg_liveness``
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values using bitwise or.
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Register parentage chains
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~~~~~~~~~~~~~~~~~~~~~~~~~
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In order to propagate information between parent and child states, a *register
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parentage chain* is established. Each register or stack slot is linked to a
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corresponding register or stack slot in its parent state via a ``->parent``
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pointer. This link is established upon state creation in ``is_state_visited()``
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and might be modified by ``set_callee_state()`` called from
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``__check_func_call()``.
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The rules for correspondence between registers / stack slots are as follows:
|
|
|
|
* For the current stack frame, registers and stack slots of the new state are
|
|
linked to the registers and stack slots of the parent state with the same
|
|
indices.
|
|
|
|
* For the outer stack frames, only caller saved registers (r6-r9) and stack
|
|
slots are linked to the registers and stack slots of the parent state with the
|
|
same indices.
|
|
|
|
* When function call is processed a new ``struct bpf_func_state`` instance is
|
|
allocated, it encapsulates a new set of registers and stack slots. For this
|
|
new frame, parent links for r6-r9 and stack slots are set to nil, parent links
|
|
for r1-r5 are set to match caller r1-r5 parent links.
|
|
|
|
This could be illustrated by the following diagram (arrows stand for
|
|
``->parent`` pointers)::
|
|
|
|
... ; Frame #0, some instructions
|
|
--- checkpoint #0 ---
|
|
1 : r6 = 42 ; Frame #0
|
|
--- checkpoint #1 ---
|
|
2 : call foo() ; Frame #0
|
|
... ; Frame #1, instructions from foo()
|
|
--- checkpoint #2 ---
|
|
... ; Frame #1, instructions from foo()
|
|
--- checkpoint #3 ---
|
|
exit ; Frame #1, return from foo()
|
|
3 : r1 = r6 ; Frame #0 <- current state
|
|
|
|
+-------------------------------+-------------------------------+
|
|
| Frame #0 | Frame #1 |
|
|
Checkpoint +-------------------------------+-------------------------------+
|
|
#0 | r0 | r1-r5 | r6-r9 | fp-8 ... |
|
|
+-------------------------------+
|
|
^ ^ ^ ^
|
|
| | | |
|
|
Checkpoint +-------------------------------+
|
|
#1 | r0 | r1-r5 | r6-r9 | fp-8 ... |
|
|
+-------------------------------+
|
|
^ ^ ^
|
|
|_______|_______|_______________
|
|
| | |
|
|
nil nil | | | nil nil
|
|
| | | | | | |
|
|
Checkpoint +-------------------------------+-------------------------------+
|
|
#2 | r0 | r1-r5 | r6-r9 | fp-8 ... | r0 | r1-r5 | r6-r9 | fp-8 ... |
|
|
+-------------------------------+-------------------------------+
|
|
^ ^ ^ ^ ^
|
|
nil nil | | | | |
|
|
| | | | | | |
|
|
Checkpoint +-------------------------------+-------------------------------+
|
|
#3 | r0 | r1-r5 | r6-r9 | fp-8 ... | r0 | r1-r5 | r6-r9 | fp-8 ... |
|
|
+-------------------------------+-------------------------------+
|
|
^ ^
|
|
nil nil | |
|
|
| | | |
|
|
Current +-------------------------------+
|
|
state | r0 | r1-r5 | r6-r9 | fp-8 ... |
|
|
+-------------------------------+
|
|
\
|
|
r6 read mark is propagated via these links
|
|
all the way up to checkpoint #1.
|
|
The checkpoint #1 contains a write mark for r6
|
|
because of instruction (1), thus read propagation
|
|
does not reach checkpoint #0 (see section below).
|
|
|
|
Liveness marks tracking
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
For each processed instruction, the verifier tracks read and written registers
|
|
and stack slots. The main idea of the algorithm is that read marks propagate
|
|
back along the state parentage chain until they hit a write mark, which 'screens
|
|
off' earlier states from the read. The information about reads is propagated by
|
|
function ``mark_reg_read()`` which could be summarized as follows::
|
|
|
|
mark_reg_read(struct bpf_reg_state *state, ...):
|
|
parent = state->parent
|
|
while parent:
|
|
if state->live & REG_LIVE_WRITTEN:
|
|
break
|
|
if parent->live & REG_LIVE_READ64:
|
|
break
|
|
parent->live |= REG_LIVE_READ64
|
|
state = parent
|
|
parent = state->parent
|
|
|
|
Notes:
|
|
|
|
* The read marks are applied to the **parent** state while write marks are
|
|
applied to the **current** state. The write mark on a register or stack slot
|
|
means that it is updated by some instruction in the straight-line code leading
|
|
from the parent state to the current state.
|
|
|
|
* Details about REG_LIVE_READ32 are omitted.
|
|
|
|
* Function ``propagate_liveness()`` (see section :ref:`read_marks_for_cache_hits`)
|
|
might override the first parent link. Please refer to the comments in the
|
|
``propagate_liveness()`` and ``mark_reg_read()`` source code for further
|
|
details.
|
|
|
|
Because stack writes could have different sizes ``REG_LIVE_WRITTEN`` marks are
|
|
applied conservatively: stack slots are marked as written only if write size
|
|
corresponds to the size of the register, e.g. see function ``save_register_state()``.
|
|
|
|
Consider the following example::
|
|
|
|
0: (*u64)(r10 - 8) = 0 ; define 8 bytes of fp-8
|
|
--- checkpoint #0 ---
|
|
1: (*u32)(r10 - 8) = 1 ; redefine lower 4 bytes
|
|
2: r1 = (*u32)(r10 - 8) ; read lower 4 bytes defined at (1)
|
|
3: r2 = (*u32)(r10 - 4) ; read upper 4 bytes defined at (0)
|
|
|
|
As stated above, the write at (1) does not count as ``REG_LIVE_WRITTEN``. Should
|
|
it be otherwise, the algorithm above wouldn't be able to propagate the read mark
|
|
from (3) to checkpoint #0.
|
|
|
|
Once the ``BPF_EXIT`` instruction is reached ``update_branch_counts()`` is
|
|
called to update the ``->branches`` counter for each verifier state in a chain
|
|
of parent verifier states. When the ``->branches`` counter reaches zero the
|
|
verifier state becomes a valid entry in a set of cached verifier states.
|
|
|
|
Each entry of the verifier states cache is post-processed by a function
|
|
``clean_live_states()``. This function marks all registers and stack slots
|
|
without ``REG_LIVE_READ{32,64}`` marks as ``NOT_INIT`` or ``STACK_INVALID``.
|
|
Registers/stack slots marked in this way are ignored in function ``stacksafe()``
|
|
called from ``states_equal()`` when a state cache entry is considered for
|
|
equivalence with a current state.
|
|
|
|
Now it is possible to explain how the example from the beginning of the section
|
|
works::
|
|
|
|
0: call bpf_get_prandom_u32()
|
|
1: r1 = 0
|
|
2: if r0 == 0 goto +1
|
|
3: r0 = 1
|
|
--- checkpoint[0] ---
|
|
4: r0 = r1
|
|
5: exit
|
|
|
|
* At instruction #2 branching point is reached and state ``{ r0 == 0, r1 == 0, pc == 4 }``
|
|
is pushed to states processing queue (pc stands for program counter).
|
|
|
|
* At instruction #4:
|
|
|
|
* ``checkpoint[0]`` states cache entry is created: ``{ r0 == 1, r1 == 0, pc == 4 }``;
|
|
* ``checkpoint[0].r0`` is marked as written;
|
|
* ``checkpoint[0].r1`` is marked as read;
|
|
|
|
* At instruction #5 exit is reached and ``checkpoint[0]`` can now be processed
|
|
by ``clean_live_states()``. After this processing ``checkpoint[0].r0`` has a
|
|
read mark and all other registers and stack slots are marked as ``NOT_INIT``
|
|
or ``STACK_INVALID``
|
|
|
|
* The state ``{ r0 == 0, r1 == 0, pc == 4 }`` is popped from the states queue
|
|
and is compared against a cached state ``{ r1 == 0, pc == 4 }``, the states
|
|
are considered equivalent.
|
|
|
|
.. _read_marks_for_cache_hits:
|
|
|
|
Read marks propagation for cache hits
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Another point is the handling of read marks when a previously verified state is
|
|
found in the states cache. Upon cache hit verifier must behave in the same way
|
|
as if the current state was verified to the program exit. This means that all
|
|
read marks, present on registers and stack slots of the cached state, must be
|
|
propagated over the parentage chain of the current state. Example below shows
|
|
why this is important. Function ``propagate_liveness()`` handles this case.
|
|
|
|
Consider the following state parentage chain (S is a starting state, A-E are
|
|
derived states, -> arrows show which state is derived from which)::
|
|
|
|
r1 read
|
|
<------------- A[r1] == 0
|
|
C[r1] == 0
|
|
S ---> A ---> B ---> exit E[r1] == 1
|
|
|
|
|
` ---> C ---> D
|
|
|
|
|
` ---> E ^
|
|
|___ suppose all these
|
|
^ states are at insn #Y
|
|
|
|
|
suppose all these
|
|
states are at insn #X
|
|
|
|
* Chain of states ``S -> A -> B -> exit`` is verified first.
|
|
|
|
* While ``B -> exit`` is verified, register ``r1`` is read and this read mark is
|
|
propagated up to state ``A``.
|
|
|
|
* When chain of states ``C -> D`` is verified the state ``D`` turns out to be
|
|
equivalent to state ``B``.
|
|
|
|
* The read mark for ``r1`` has to be propagated to state ``C``, otherwise state
|
|
``C`` might get mistakenly marked as equivalent to state ``E`` even though
|
|
values for register ``r1`` differ between ``C`` and ``E``.
|
|
|
|
Understanding eBPF verifier messages
|
|
====================================
|
|
|
|
The following are few examples of invalid eBPF programs and verifier error
|
|
messages as seen in the log:
|
|
|
|
Program with unreachable instructions::
|
|
|
|
static struct bpf_insn prog[] = {
|
|
BPF_EXIT_INSN(),
|
|
BPF_EXIT_INSN(),
|
|
};
|
|
|
|
Error::
|
|
|
|
unreachable insn 1
|
|
|
|
Program that reads uninitialized register::
|
|
|
|
BPF_MOV64_REG(BPF_REG_0, BPF_REG_2),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (bf) r0 = r2
|
|
R2 !read_ok
|
|
|
|
Program that doesn't initialize R0 before exiting::
|
|
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_1),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (bf) r2 = r1
|
|
1: (95) exit
|
|
R0 !read_ok
|
|
|
|
Program that accesses stack out of bounds::
|
|
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_10, 8, 0),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (7a) *(u64 *)(r10 +8) = 0
|
|
invalid stack off=8 size=8
|
|
|
|
Program that doesn't initialize stack before passing its address into function::
|
|
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_LD_MAP_FD(BPF_REG_1, 0),
|
|
BPF_RAW_INSN(BPF_JMP | BPF_CALL, 0, 0, 0, BPF_FUNC_map_lookup_elem),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (bf) r2 = r10
|
|
1: (07) r2 += -8
|
|
2: (b7) r1 = 0x0
|
|
3: (85) call 1
|
|
invalid indirect read from stack off -8+0 size 8
|
|
|
|
Program that uses invalid map_fd=0 while calling to map_lookup_elem() function::
|
|
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_10, -8, 0),
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_LD_MAP_FD(BPF_REG_1, 0),
|
|
BPF_RAW_INSN(BPF_JMP | BPF_CALL, 0, 0, 0, BPF_FUNC_map_lookup_elem),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (7a) *(u64 *)(r10 -8) = 0
|
|
1: (bf) r2 = r10
|
|
2: (07) r2 += -8
|
|
3: (b7) r1 = 0x0
|
|
4: (85) call 1
|
|
fd 0 is not pointing to valid bpf_map
|
|
|
|
Program that doesn't check return value of map_lookup_elem() before accessing
|
|
map element::
|
|
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_10, -8, 0),
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_LD_MAP_FD(BPF_REG_1, 0),
|
|
BPF_RAW_INSN(BPF_JMP | BPF_CALL, 0, 0, 0, BPF_FUNC_map_lookup_elem),
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_0, 0, 0),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (7a) *(u64 *)(r10 -8) = 0
|
|
1: (bf) r2 = r10
|
|
2: (07) r2 += -8
|
|
3: (b7) r1 = 0x0
|
|
4: (85) call 1
|
|
5: (7a) *(u64 *)(r0 +0) = 0
|
|
R0 invalid mem access 'map_value_or_null'
|
|
|
|
Program that correctly checks map_lookup_elem() returned value for NULL, but
|
|
accesses the memory with incorrect alignment::
|
|
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_10, -8, 0),
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_LD_MAP_FD(BPF_REG_1, 0),
|
|
BPF_RAW_INSN(BPF_JMP | BPF_CALL, 0, 0, 0, BPF_FUNC_map_lookup_elem),
|
|
BPF_JMP_IMM(BPF_JEQ, BPF_REG_0, 0, 1),
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_0, 4, 0),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (7a) *(u64 *)(r10 -8) = 0
|
|
1: (bf) r2 = r10
|
|
2: (07) r2 += -8
|
|
3: (b7) r1 = 1
|
|
4: (85) call 1
|
|
5: (15) if r0 == 0x0 goto pc+1
|
|
R0=map_ptr R10=fp
|
|
6: (7a) *(u64 *)(r0 +4) = 0
|
|
misaligned access off 4 size 8
|
|
|
|
Program that correctly checks map_lookup_elem() returned value for NULL and
|
|
accesses memory with correct alignment in one side of 'if' branch, but fails
|
|
to do so in the other side of 'if' branch::
|
|
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_10, -8, 0),
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_LD_MAP_FD(BPF_REG_1, 0),
|
|
BPF_RAW_INSN(BPF_JMP | BPF_CALL, 0, 0, 0, BPF_FUNC_map_lookup_elem),
|
|
BPF_JMP_IMM(BPF_JEQ, BPF_REG_0, 0, 2),
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_0, 0, 0),
|
|
BPF_EXIT_INSN(),
|
|
BPF_ST_MEM(BPF_DW, BPF_REG_0, 0, 1),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (7a) *(u64 *)(r10 -8) = 0
|
|
1: (bf) r2 = r10
|
|
2: (07) r2 += -8
|
|
3: (b7) r1 = 1
|
|
4: (85) call 1
|
|
5: (15) if r0 == 0x0 goto pc+2
|
|
R0=map_ptr R10=fp
|
|
6: (7a) *(u64 *)(r0 +0) = 0
|
|
7: (95) exit
|
|
|
|
from 5 to 8: R0=imm0 R10=fp
|
|
8: (7a) *(u64 *)(r0 +0) = 1
|
|
R0 invalid mem access 'imm'
|
|
|
|
Program that performs a socket lookup then sets the pointer to NULL without
|
|
checking it::
|
|
|
|
BPF_MOV64_IMM(BPF_REG_2, 0),
|
|
BPF_STX_MEM(BPF_W, BPF_REG_10, BPF_REG_2, -8),
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_MOV64_IMM(BPF_REG_3, 4),
|
|
BPF_MOV64_IMM(BPF_REG_4, 0),
|
|
BPF_MOV64_IMM(BPF_REG_5, 0),
|
|
BPF_EMIT_CALL(BPF_FUNC_sk_lookup_tcp),
|
|
BPF_MOV64_IMM(BPF_REG_0, 0),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (b7) r2 = 0
|
|
1: (63) *(u32 *)(r10 -8) = r2
|
|
2: (bf) r2 = r10
|
|
3: (07) r2 += -8
|
|
4: (b7) r3 = 4
|
|
5: (b7) r4 = 0
|
|
6: (b7) r5 = 0
|
|
7: (85) call bpf_sk_lookup_tcp#65
|
|
8: (b7) r0 = 0
|
|
9: (95) exit
|
|
Unreleased reference id=1, alloc_insn=7
|
|
|
|
Program that performs a socket lookup but does not NULL-check the returned
|
|
value::
|
|
|
|
BPF_MOV64_IMM(BPF_REG_2, 0),
|
|
BPF_STX_MEM(BPF_W, BPF_REG_10, BPF_REG_2, -8),
|
|
BPF_MOV64_REG(BPF_REG_2, BPF_REG_10),
|
|
BPF_ALU64_IMM(BPF_ADD, BPF_REG_2, -8),
|
|
BPF_MOV64_IMM(BPF_REG_3, 4),
|
|
BPF_MOV64_IMM(BPF_REG_4, 0),
|
|
BPF_MOV64_IMM(BPF_REG_5, 0),
|
|
BPF_EMIT_CALL(BPF_FUNC_sk_lookup_tcp),
|
|
BPF_EXIT_INSN(),
|
|
|
|
Error::
|
|
|
|
0: (b7) r2 = 0
|
|
1: (63) *(u32 *)(r10 -8) = r2
|
|
2: (bf) r2 = r10
|
|
3: (07) r2 += -8
|
|
4: (b7) r3 = 4
|
|
5: (b7) r4 = 0
|
|
6: (b7) r5 = 0
|
|
7: (85) call bpf_sk_lookup_tcp#65
|
|
8: (95) exit
|
|
Unreleased reference id=1, alloc_insn=7
|