Contents

1 BPF Instruction Set Architecture (ISA)¶

This document specifies the BPF instruction set architecture (ISA).

1.1 Documentation conventions ¶

For brevity and consistency, this document refers to families of types using a shorthand syntax and refers to several expository, mnemonic functions when describing the semantics of instructions. The range of valid values for those types and the semantics of those functions are defined in the following subsections.

1.1.1 Types ¶

This document refers to integer types with the notation SN to specify a type’s signedness (S) and bit width (N), respectively.

Meaning of signedness notation.¶
S	Meaning
u	unsigned
s	signed

Meaning of bit-width notation.¶
N	Bit width
8	8 bits
16	16 bits
32	32 bits
64	64 bits
128	128 bits

For example, u32 is a type whose valid values are all the 32-bit unsigned numbers and s16 is a types whose valid values are all the 16-bit signed numbers.

1.1.2 Functions ¶

htobe16: Takes an unsigned 16-bit number in host-endian format and returns the equivalent number as an unsigned 16-bit number in big-endian format.
htobe32: Takes an unsigned 32-bit number in host-endian format and returns the equivalent number as an unsigned 32-bit number in big-endian format.
htobe64: Takes an unsigned 64-bit number in host-endian format and returns the equivalent number as an unsigned 64-bit number in big-endian format.
htole16: Takes an unsigned 16-bit number in host-endian format and returns the equivalent number as an unsigned 16-bit number in little-endian format.
htole32: Takes an unsigned 32-bit number in host-endian format and returns the equivalent number as an unsigned 32-bit number in little-endian format.
htole64: Takes an unsigned 64-bit number in host-endian format and returns the equivalent number as an unsigned 64-bit number in little-endian format.
bswap16: Takes an unsigned 16-bit number in either big- or little-endian format and returns the equivalent number with the same bit width but opposite endianness.
bswap32: Takes an unsigned 32-bit number in either big- or little-endian format and returns the equivalent number with the same bit width but opposite endianness.
bswap64: Takes an unsigned 64-bit number in either big- or little-endian format and returns the equivalent number with the same bit width but opposite endianness.

1.1.3 Definitions ¶

Sign Extend¶

To sign extend an X -bit number, A, to a Y -bit number, B , means to

Copy all X bits from A to the lower X bits of B.
Set the value of the remaining Y - X bits of B to the value of the most-significant bit of A.

Example

Sign extend an 8-bit number A to a 16-bit number B on a big-endian platform:

A:          10000110
B: 11111111 10000110

1.1.4 Conformance groups ¶

An implementation does not need to support all instructions specified in this document (e.g., deprecated instructions). Instead, a number of conformance groups are specified. An implementation must support the base32 conformance group and may support additional conformance groups, where supporting a conformance group means it must support all instructions in that conformance group.

The use of named conformance groups enables interoperability between a runtime that executes instructions, and tools as such compilers that generate instructions for the runtime. Thus, capability discovery in terms of conformance groups might be done manually by users or automatically by tools.

Each conformance group has a short ASCII label (e.g., “base32”) that corresponds to a set of instructions that are mandatory. That is, each instruction has one or more conformance groups of which it is a member.

This document defines the following conformance groups:

base32: includes all instructions defined in this specification unless otherwise noted.
base64: includes base32, plus instructions explicitly noted as being in the base64 conformance group.
atomic32: includes 32-bit atomic operation instructions (see Atomic operations).
atomic64: includes atomic32, plus 64-bit atomic operation instructions.
divmul32: includes 32-bit division, multiplication, and modulo instructions.
divmul64: includes divmul32, plus 64-bit division, multiplication, and modulo instructions.
packet: deprecated packet access instructions.

1.2 Instruction encoding ¶

BPF has two instruction encodings:

the basic instruction encoding, which uses 64 bits to encode an instruction
the wide instruction encoding, which appends a second 64 bits after the basic instruction for a total of 128 bits.

1.2.1 Basic instruction encoding ¶

A basic instruction is encoded as follows:

+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|    opcode     |     regs      |            offset             |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                              imm                              |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

opcode

operation to perform, encoded as follows:

+-+-+-+-+-+-+-+-+
|specific |class|
+-+-+-+-+-+-+-+-+

specific: The format of these bits varies by instruction class
class: The instruction class (see Instruction classes)

regs

The source and destination register numbers, encoded as follows on a little-endian host:

+-+-+-+-+-+-+-+-+
|src_reg|dst_reg|
+-+-+-+-+-+-+-+-+

and as follows on a big-endian host:

+-+-+-+-+-+-+-+-+
|dst_reg|src_reg|
+-+-+-+-+-+-+-+-+

src_reg: the source register number (0-10), except where otherwise specified (64-bit immediate instructions reuse this field for other purposes)
dst_reg: destination register number (0-10)

offset

signed integer offset used with pointer arithmetic

imm

signed integer immediate value

Note that the contents of multi-byte fields (‘offset’ and ‘imm’) are stored using big-endian byte ordering on big-endian hosts and little-endian byte ordering on little-endian hosts.

For example:

opcode                  offset imm          assembly
       src_reg dst_reg
07     0       1        00 00  44 33 22 11  r1 += 0x11223344 // little
       dst_reg src_reg
07     1       0        00 00  11 22 33 44  r1 += 0x11223344 // big

Note that most instructions do not use all of the fields. Unused fields shall be cleared to zero.

1.2.2 Wide instruction encoding ¶

Some instructions are defined to use the wide instruction encoding, which uses two 32-bit immediate values. The 64 bits following the basic instruction format contain a pseudo instruction with ‘opcode’, ‘dst_reg’, ‘src_reg’, and ‘offset’ all set to zero.

This is depicted in the following figure:

+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|    opcode     |     regs      |            offset             |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                              imm                              |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                           reserved                            |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|                           next_imm                            |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

opcode: operation to perform, encoded as explained above
regs: The source and destination register numbers, encoded as explained above
offset: signed integer offset used with pointer arithmetic
imm: signed integer immediate value
reserved: unused, set to zero
next_imm: second signed integer immediate value

1.2.3 Instruction classes ¶

The three least significant bits of the ‘opcode’ field store the instruction class:

class	value	description	reference
LD	0x0	non-standard load operations	Load and store instructions
LDX	0x1	load into register operations	Load and store instructions
ST	0x2	store from immediate operations	Load and store instructions
STX	0x3	store from register operations	Load and store instructions
ALU	0x4	32-bit arithmetic operations	Arithmetic and jump instructions
JMP	0x5	64-bit jump operations	Arithmetic and jump instructions
JMP32	0x6	32-bit jump operations	Arithmetic and jump instructions
ALU64	0x7	64-bit arithmetic operations	Arithmetic and jump instructions

1.3 Arithmetic and jump instructions ¶

For arithmetic and jump instructions (ALU, ALU64, JMP and JMP32), the 8-bit ‘opcode’ field is divided into three parts:

+-+-+-+-+-+-+-+-+
|  code |s|class|
+-+-+-+-+-+-+-+-+

code

the operation code, whose meaning varies by instruction class

s (source)

the source operand location, which unless otherwise specified is one of:

source	value	description
K	0	use 32-bit ‘imm’ value as source operand
X	1	use ‘src_reg’ register value as source operand

instruction class

the instruction class (see Instruction classes)

1.3.1 Arithmetic instructions ¶

ALU uses 32-bit wide operands while ALU64 uses 64-bit wide operands for otherwise identical operations. ALU64 instructions belong to the base64 conformance group unless noted otherwise. The ‘code’ field encodes the operation as below, where ‘src’ and ‘dst’ refer to the values of the source and destination registers, respectively.

name	code	offset	description
ADD	0x0	0	dst += src
SUB	0x1	0	dst -= src
MUL	0x2	0	dst *= src
DIV	0x3	0	dst = (src != 0) ? (dst / src) : 0
SDIV	0x3	1	dst = (src != 0) ? (dst s/ src) : 0
OR	0x4	0	dst \|= src
AND	0x5	0	dst &= src
LSH	0x6	0	dst <<= (src & mask)
RSH	0x7	0	dst >>= (src & mask)
NEG	0x8	0	dst = -dst
MOD	0x9	0	dst = (src != 0) ? (dst % src) : dst
SMOD	0x9	1	dst = (src != 0) ? (dst s% src) : dst
XOR	0xa	0	dst ^= src
MOV	0xb	0	dst = src
MOVSX	0xb	8/16/32	dst = (s8,s16,s32)src
ARSH	0xc	0	sign extending dst >>= (src & mask)
END	0xd	0	byte swap operations (see Byte swap instructions below)

Underflow and overflow are allowed during arithmetic operations, meaning the 64-bit or 32-bit value will wrap. If BPF program execution would result in division by zero, the destination register is instead set to zero. If execution would result in modulo by zero, for ALU64 the value of the destination register is unchanged whereas for ALU the upper 32 bits of the destination register are zeroed.

{ADD, X, ALU}, where ‘code’ = ADD, ‘source’ = X, and ‘class’ = ALU, means:

dst = (u32) ((u32) dst + (u32) src)

where ‘(u32)’ indicates that the upper 32 bits are zeroed.

{ADD, X, ALU64} means:

dst = dst + src

{XOR, K, ALU} means:

dst = (u32) dst ^ (u32) imm

{XOR, K, ALU64} means:

dst = dst ^ imm

Note that most instructions have instruction offset of 0. Only three instructions (SDIV, SMOD, MOVSX) have a non-zero offset.

Division, multiplication, and modulo operations for ALU are part of the “divmul32” conformance group, and division, multiplication, and modulo operations for ALU64 are part of the “divmul64” conformance group. The division and modulo operations support both unsigned and signed flavors.

For unsigned operations (DIV and MOD), for ALU, ‘imm’ is interpreted as a 32-bit unsigned value. For ALU64, ‘imm’ is first sign extended from 32 to 64 bits, and then interpreted as a 64-bit unsigned value.

For signed operations (SDIV and SMOD), for ALU, ‘imm’ is interpreted as a 32-bit signed value. For ALU64, ‘imm’ is first sign extended from 32 to 64 bits, and then interpreted as a 64-bit signed value.

Note that there are varying definitions of the signed modulo operation when the dividend or divisor are negative, where implementations often vary by language such that Python, Ruby, etc. differ from C, Go, Java, etc. This specification requires that signed modulo use truncated division (where -13 % 3 == -1) as implemented in C, Go, etc.:

a % n = a - n * trunc(a / n)

The MOVSX instruction does a move operation with sign extension. {MOVSX, X, ALU} sign extends 8-bit and 16-bit operands into 32 bit operands, and zeroes the remaining upper 32 bits. {MOVSX, X, ALU64} sign extends 8-bit, 16-bit, and 32-bit operands into 64 bit operands. Unlike other arithmetic instructions, MOVSX is only defined for register source operands (X).

The NEG instruction is only defined when the source bit is clear (K).

Shift operations use a mask of 0x3F (63) for 64-bit operations and 0x1F (31) for 32-bit operations.

1.3.2 Byte swap instructions ¶

The byte swap instructions use instruction classes of ALU and ALU64 and a 4-bit ‘code’ field of END.

The byte swap instructions operate on the destination register only and do not use a separate source register or immediate value.

For ALU, the 1-bit source operand field in the opcode is used to select what byte order the operation converts from or to. For ALU64, the 1-bit source operand field in the opcode is reserved and must be set to 0.

class	source	value	description
ALU	TO_LE	0	convert between host byte order and little endian
ALU	TO_BE	1	convert between host byte order and big endian
ALU64	Reserved	0	do byte swap unconditionally

The ‘imm’ field encodes the width of the swap operations. The following widths are supported: 16, 32 and 64. Width 64 operations belong to the base64 conformance group and other swap operations belong to the base32 conformance group.

Examples:

{END, TO_LE, ALU} with imm = 16/32/64 means:

dst = htole16(dst)
dst = htole32(dst)
dst = htole64(dst)

{END, TO_BE, ALU} with imm = 16/32/64 means:

dst = htobe16(dst)
dst = htobe32(dst)
dst = htobe64(dst)

{END, TO_LE, ALU64} with imm = 16/32/64 means:

dst = bswap16(dst)
dst = bswap32(dst)
dst = bswap64(dst)

1.3.3 Jump instructions ¶

JMP32 uses 32-bit wide operands and indicates the base32 conformance group, while JMP uses 64-bit wide operands for otherwise identical operations, and indicates the base64 conformance group unless otherwise specified. The ‘code’ field encodes the operation as below:

code	value	src_reg	description	notes
JA	0x0	0x0	PC += offset	{JA, K, JMP} only
JA	0x0	0x0	PC += imm	{JA, K, JMP32} only
JEQ	0x1	any	PC += offset if dst == src
JGT	0x2	any	PC += offset if dst > src	unsigned
JGE	0x3	any	PC += offset if dst >= src	unsigned
JSET	0x4	any	PC += offset if dst & src
JNE	0x5	any	PC += offset if dst != src
JSGT	0x6	any	PC += offset if dst > src	signed
JSGE	0x7	any	PC += offset if dst >= src	signed
CALL	0x8	0x0	call helper function by address	{CALL, K, JMP} only, see Helper functions
CALL	0x8	0x1	call PC += imm	{CALL, K, JMP} only, see Program-local functions
CALL	0x8	0x2	call helper function by BTF ID	{CALL, K, JMP} only, see Helper functions
EXIT	0x9	0x0	return	{CALL, K, JMP} only
JLT	0xa	any	PC += offset if dst < src	unsigned
JLE	0xb	any	PC += offset if dst <= src	unsigned
JSLT	0xc	any	PC += offset if dst < src	signed
JSLE	0xd	any	PC += offset if dst <= src	signed

The BPF program needs to store the return value into register R0 before doing an EXIT.

Example:

{JSGE, X, JMP32} means:

if (s32)dst s>= (s32)src goto +offset

where ‘s>=’ indicates a signed ‘>=’ comparison.

{JA, K, JMP32} means:

gotol +imm

where ‘imm’ means the branch offset comes from insn ‘imm’ field.

Note that there are two flavors of JA instructions. The JMP class permits a 16-bit jump offset specified by the ‘offset’ field, whereas the JMP32 class permits a 32-bit jump offset specified by the ‘imm’ field. A > 16-bit conditional jump may be converted to a < 16-bit conditional jump plus a 32-bit unconditional jump.

All CALL and JA instructions belong to the base32 conformance group.

1.3.3.1 Helper functions ¶

Helper functions are a concept whereby BPF programs can call into a set of function calls exposed by the underlying platform.

Historically, each helper function was identified by an address encoded in the imm field. The available helper functions may differ for each program type, but address values are unique across all program types.

Platforms that support the BPF Type Format (BTF) support identifying a helper function by a BTF ID encoded in the imm field, where the BTF ID identifies the helper name and type.

1.3.3.2 Program-local functions ¶

Program-local functions are functions exposed by the same BPF program as the caller, and are referenced by offset from the call instruction, similar to JA. The offset is encoded in the imm field of the call instruction. A EXIT within the program-local function will return to the caller.

1.4 Load and store instructions ¶

For load and store instructions (LD, LDX, ST, and STX), the 8-bit ‘opcode’ field is divided as:

+-+-+-+-+-+-+-+-+
|mode |sz |class|
+-+-+-+-+-+-+-+-+

mode

The mode modifier is one of:

mode modifier

value

description

reference

IMM

0

64-bit immediate instructions

64-bit immediate instructions

ABS

1

legacy BPF packet access (absolute)

Legacy BPF Packet access instructions

IND

2

legacy BPF packet access (indirect)

Legacy BPF Packet access instructions

MEM

3

regular load and store operations

Regular load and store operations

MEMSX

4

sign-extension load operations

Sign-extension load operations

ATOMIC

6

atomic operations

Atomic operations

sz (size)

The size modifier is one of:

size

value

description

W

0

word (4 bytes)

H

1

half word (2 bytes)

B

2

byte

DW

3

double word (8 bytes)

Instructions using DW belong to the base64 conformance group.

class

The instruction class (see Instruction classes)

1.4.1 Regular load and store operations ¶

The MEM mode modifier is used to encode regular load and store instructions that transfer data between a register and memory.

{MEM, <size>, STX} means:

*(size *) (dst + offset) = src

{MEM, <size>, ST} means:

*(size *) (dst + offset) = imm

{MEM, <size>, LDX} means:

dst = *(unsigned size *) (src + offset)

Where ‘<size>’ is one of: B, H, W, or DW, and ‘unsigned size’ is one of: u8, u16, u32, or u64.

1.4.2 Sign-extension load operations ¶

The MEMSX mode modifier is used to encode sign-extension load instructions that transfer data between a register and memory.

{MEMSX, <size>, LDX} means:

dst = *(signed size *) (src + offset)

Where size is one of: B, H, or W, and ‘signed size’ is one of: s8, s16, or s32.

1.4.3 Atomic operations ¶

Atomic operations are operations that operate on memory and can not be interrupted or corrupted by other access to the same memory region by other BPF programs or means outside of this specification.

All atomic operations supported by BPF are encoded as store operations that use the ATOMIC mode modifier as follows:

{ATOMIC, W, STX} for 32-bit operations, which are part of the “atomic32” conformance group.
{ATOMIC, DW, STX} for 64-bit operations, which are part of the “atomic64” conformance group.
8-bit and 16-bit wide atomic operations are not supported.

The ‘imm’ field is used to encode the actual atomic operation. Simple atomic operation use a subset of the values defined to encode arithmetic operations in the ‘imm’ field to encode the atomic operation:

imm	value	description
ADD	0x00	atomic add
OR	0x40	atomic or
AND	0x50	atomic and
XOR	0xa0	atomic xor

{ATOMIC, W, STX} with ‘imm’ = ADD means:

*(u32 *)(dst + offset) += src

{ATOMIC, DW, STX} with ‘imm’ = ADD means:

*(u64 *)(dst + offset) += src

In addition to the simple atomic operations, there also is a modifier and two complex atomic operations:

imm	value	description
FETCH	0x01	modifier: return old value
XCHG	0xe0 \| FETCH	atomic exchange
CMPXCHG	0xf0 \| FETCH	atomic compare and exchange

The FETCH modifier is optional for simple atomic operations, and always set for the complex atomic operations. If the FETCH flag is set, then the operation also overwrites src with the value that was in memory before it was modified.

The XCHG operation atomically exchanges src with the value addressed by dst + offset.

The CMPXCHG operation atomically compares the value addressed by dst + offset with R0. If they match, the value addressed by dst + offset is replaced with src. In either case, the value that was at dst + offset before the operation is zero-extended and loaded back to R0.

1.4.4 64-bit immediate instructions ¶

Instructions with the IMM ‘mode’ modifier use the wide instruction encoding defined in Instruction encoding, and use the ‘src_reg’ field of the basic instruction to hold an opcode subtype.

The following table defines a set of {IMM, DW, LD} instructions with opcode subtypes in the ‘src_reg’ field, using new terms such as “map” defined further below:

src_reg	pseudocode	imm type	dst type
0x0	dst = (next_imm << 32) \| imm	integer	integer
0x1	dst = map_by_fd(imm)	map fd	map
0x2	dst = map_val(map_by_fd(imm)) + next_imm	map fd	data pointer
0x3	dst = var_addr(imm)	variable id	data pointer
0x4	dst = code_addr(imm)	integer	code pointer
0x5	dst = map_by_idx(imm)	map index	map
0x6	dst = map_val(map_by_idx(imm)) + next_imm	map index	data pointer

where

map_by_fd(imm) means to convert a 32-bit file descriptor into an address of a map (see Maps)
map_by_idx(imm) means to convert a 32-bit index into an address of a map
map_val(map) gets the address of the first value in a given map
var_addr(imm) gets the address of a platform variable (see Platform Variables) with a given id
code_addr(imm) gets the address of the instruction at a specified relative offset in number of (64-bit) instructions
the ‘imm type’ can be used by disassemblers for display
the ‘dst type’ can be used for verification and JIT compilation purposes

1.4.4.1 Maps ¶

Maps are shared memory regions accessible by BPF programs on some platforms. A map can have various semantics as defined in a separate document, and may or may not have a single contiguous memory region, but the ‘map_val(map)’ is currently only defined for maps that do have a single contiguous memory region.

Each map can have a file descriptor (fd) if supported by the platform, where ‘map_by_fd(imm)’ means to get the map with the specified file descriptor. Each BPF program can also be defined to use a set of maps associated with the program at load time, and ‘map_by_idx(imm)’ means to get the map with the given index in the set associated with the BPF program containing the instruction.

1.4.4.2 Platform Variables ¶

Platform variables are memory regions, identified by integer ids, exposed by the runtime and accessible by BPF programs on some platforms. The ‘var_addr(imm)’ operation means to get the address of the memory region identified by the given id.

1.4.5 Legacy BPF Packet access instructions ¶

BPF previously introduced special instructions for access to packet data that were carried over from classic BPF. These instructions used an instruction class of LD, a size modifier of W, H, or B, and a mode modifier of ABS or IND. The ‘dst_reg’ and ‘offset’ fields were set to zero, and ‘src_reg’ was set to zero for ABS. However, these instructions are deprecated and should no longer be used. All legacy packet access instructions belong to the “packet” conformance group.

The Linux Kernel