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moby--moby/vendor/github.com/cilium/ebpf/asm/instruction.go

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package asm
import (
"crypto/sha1"
"encoding/binary"
"encoding/hex"
"errors"
"fmt"
"io"
"math"
"strings"
"github.com/cilium/ebpf/internal/unix"
)
// InstructionSize is the size of a BPF instruction in bytes
const InstructionSize = 8
// RawInstructionOffset is an offset in units of raw BPF instructions.
type RawInstructionOffset uint64
// Bytes returns the offset of an instruction in bytes.
func (rio RawInstructionOffset) Bytes() uint64 {
return uint64(rio) * InstructionSize
}
// Instruction is a single eBPF instruction.
type Instruction struct {
OpCode OpCode
Dst Register
Src Register
Offset int16
Constant int64
Reference string
Symbol string
}
// Sym creates a symbol.
func (ins Instruction) Sym(name string) Instruction {
ins.Symbol = name
return ins
}
// Unmarshal decodes a BPF instruction.
func (ins *Instruction) Unmarshal(r io.Reader, bo binary.ByteOrder) (uint64, error) {
var bi bpfInstruction
err := binary.Read(r, bo, &bi)
if err != nil {
return 0, err
}
ins.OpCode = bi.OpCode
ins.Offset = bi.Offset
ins.Constant = int64(bi.Constant)
ins.Dst, ins.Src, err = bi.Registers.Unmarshal(bo)
if err != nil {
return 0, fmt.Errorf("can't unmarshal registers: %s", err)
}
if !bi.OpCode.IsDWordLoad() {
return InstructionSize, nil
}
var bi2 bpfInstruction
if err := binary.Read(r, bo, &bi2); err != nil {
// No Wrap, to avoid io.EOF clash
return 0, errors.New("64bit immediate is missing second half")
}
if bi2.OpCode != 0 || bi2.Offset != 0 || bi2.Registers != 0 {
return 0, errors.New("64bit immediate has non-zero fields")
}
ins.Constant = int64(uint64(uint32(bi2.Constant))<<32 | uint64(uint32(bi.Constant)))
return 2 * InstructionSize, nil
}
// Marshal encodes a BPF instruction.
func (ins Instruction) Marshal(w io.Writer, bo binary.ByteOrder) (uint64, error) {
if ins.OpCode == InvalidOpCode {
return 0, errors.New("invalid opcode")
}
isDWordLoad := ins.OpCode.IsDWordLoad()
cons := int32(ins.Constant)
if isDWordLoad {
// Encode least significant 32bit first for 64bit operations.
cons = int32(uint32(ins.Constant))
}
regs, err := newBPFRegisters(ins.Dst, ins.Src, bo)
if err != nil {
return 0, fmt.Errorf("can't marshal registers: %s", err)
}
bpfi := bpfInstruction{
ins.OpCode,
regs,
ins.Offset,
cons,
}
if err := binary.Write(w, bo, &bpfi); err != nil {
return 0, err
}
if !isDWordLoad {
return InstructionSize, nil
}
bpfi = bpfInstruction{
Constant: int32(ins.Constant >> 32),
}
if err := binary.Write(w, bo, &bpfi); err != nil {
return 0, err
}
return 2 * InstructionSize, nil
}
// RewriteMapPtr changes an instruction to use a new map fd.
//
// Returns an error if the instruction doesn't load a map.
func (ins *Instruction) RewriteMapPtr(fd int) error {
if !ins.OpCode.IsDWordLoad() {
return fmt.Errorf("%s is not a 64 bit load", ins.OpCode)
}
if ins.Src != PseudoMapFD && ins.Src != PseudoMapValue {
return errors.New("not a load from a map")
}
// Preserve the offset value for direct map loads.
offset := uint64(ins.Constant) & (math.MaxUint32 << 32)
rawFd := uint64(uint32(fd))
ins.Constant = int64(offset | rawFd)
return nil
}
// MapPtr returns the map fd for this instruction.
//
// The result is undefined if the instruction is not a load from a map,
// see IsLoadFromMap.
func (ins *Instruction) MapPtr() int {
return int(int32(uint64(ins.Constant) & math.MaxUint32))
}
// RewriteMapOffset changes the offset of a direct load from a map.
//
// Returns an error if the instruction is not a direct load.
func (ins *Instruction) RewriteMapOffset(offset uint32) error {
if !ins.OpCode.IsDWordLoad() {
return fmt.Errorf("%s is not a 64 bit load", ins.OpCode)
}
if ins.Src != PseudoMapValue {
return errors.New("not a direct load from a map")
}
fd := uint64(ins.Constant) & math.MaxUint32
ins.Constant = int64(uint64(offset)<<32 | fd)
return nil
}
func (ins *Instruction) mapOffset() uint32 {
return uint32(uint64(ins.Constant) >> 32)
}
// IsLoadFromMap returns true if the instruction loads from a map.
//
// This covers both loading the map pointer and direct map value loads.
func (ins *Instruction) IsLoadFromMap() bool {
return ins.OpCode == LoadImmOp(DWord) && (ins.Src == PseudoMapFD || ins.Src == PseudoMapValue)
}
// IsFunctionCall returns true if the instruction calls another BPF function.
//
// This is not the same thing as a BPF helper call.
func (ins *Instruction) IsFunctionCall() bool {
return ins.OpCode.JumpOp() == Call && ins.Src == PseudoCall
}
// IsConstantLoad returns true if the instruction loads a constant of the
// given size.
func (ins *Instruction) IsConstantLoad(size Size) bool {
return ins.OpCode == LoadImmOp(size) && ins.Src == R0 && ins.Offset == 0
}
// Format implements fmt.Formatter.
func (ins Instruction) Format(f fmt.State, c rune) {
if c != 'v' {
fmt.Fprintf(f, "{UNRECOGNIZED: %c}", c)
return
}
op := ins.OpCode
if op == InvalidOpCode {
fmt.Fprint(f, "INVALID")
return
}
// Omit trailing space for Exit
if op.JumpOp() == Exit {
fmt.Fprint(f, op)
return
}
if ins.IsLoadFromMap() {
fd := ins.MapPtr()
switch ins.Src {
case PseudoMapFD:
fmt.Fprintf(f, "LoadMapPtr dst: %s fd: %d", ins.Dst, fd)
case PseudoMapValue:
fmt.Fprintf(f, "LoadMapValue dst: %s, fd: %d off: %d", ins.Dst, fd, ins.mapOffset())
}
goto ref
}
fmt.Fprintf(f, "%v ", op)
switch cls := op.Class(); cls {
case LdClass, LdXClass, StClass, StXClass:
switch op.Mode() {
case ImmMode:
fmt.Fprintf(f, "dst: %s imm: %d", ins.Dst, ins.Constant)
case AbsMode:
fmt.Fprintf(f, "imm: %d", ins.Constant)
case IndMode:
fmt.Fprintf(f, "dst: %s src: %s imm: %d", ins.Dst, ins.Src, ins.Constant)
case MemMode:
fmt.Fprintf(f, "dst: %s src: %s off: %d imm: %d", ins.Dst, ins.Src, ins.Offset, ins.Constant)
case XAddMode:
fmt.Fprintf(f, "dst: %s src: %s", ins.Dst, ins.Src)
}
case ALU64Class, ALUClass:
fmt.Fprintf(f, "dst: %s ", ins.Dst)
if op.ALUOp() == Swap || op.Source() == ImmSource {
fmt.Fprintf(f, "imm: %d", ins.Constant)
} else {
fmt.Fprintf(f, "src: %s", ins.Src)
}
case JumpClass:
switch jop := op.JumpOp(); jop {
case Call:
if ins.Src == PseudoCall {
// bpf-to-bpf call
fmt.Fprint(f, ins.Constant)
} else {
fmt.Fprint(f, BuiltinFunc(ins.Constant))
}
default:
fmt.Fprintf(f, "dst: %s off: %d ", ins.Dst, ins.Offset)
if op.Source() == ImmSource {
fmt.Fprintf(f, "imm: %d", ins.Constant)
} else {
fmt.Fprintf(f, "src: %s", ins.Src)
}
}
}
ref:
if ins.Reference != "" {
fmt.Fprintf(f, " <%s>", ins.Reference)
}
}
// Instructions is an eBPF program.
type Instructions []Instruction
func (insns Instructions) String() string {
return fmt.Sprint(insns)
}
// RewriteMapPtr rewrites all loads of a specific map pointer to a new fd.
//
// Returns an error if the symbol isn't used, see IsUnreferencedSymbol.
func (insns Instructions) RewriteMapPtr(symbol string, fd int) error {
if symbol == "" {
return errors.New("empty symbol")
}
found := false
for i := range insns {
ins := &insns[i]
if ins.Reference != symbol {
continue
}
if err := ins.RewriteMapPtr(fd); err != nil {
return err
}
found = true
}
if !found {
return &unreferencedSymbolError{symbol}
}
return nil
}
// SymbolOffsets returns the set of symbols and their offset in
// the instructions.
func (insns Instructions) SymbolOffsets() (map[string]int, error) {
offsets := make(map[string]int)
for i, ins := range insns {
if ins.Symbol == "" {
continue
}
if _, ok := offsets[ins.Symbol]; ok {
return nil, fmt.Errorf("duplicate symbol %s", ins.Symbol)
}
offsets[ins.Symbol] = i
}
return offsets, nil
}
// ReferenceOffsets returns the set of references and their offset in
// the instructions.
func (insns Instructions) ReferenceOffsets() map[string][]int {
offsets := make(map[string][]int)
for i, ins := range insns {
if ins.Reference == "" {
continue
}
offsets[ins.Reference] = append(offsets[ins.Reference], i)
}
return offsets
}
// Format implements fmt.Formatter.
//
// You can control indentation of symbols by
// specifying a width. Setting a precision controls the indentation of
// instructions.
// The default character is a tab, which can be overridden by specifying
// the ' ' space flag.
func (insns Instructions) Format(f fmt.State, c rune) {
if c != 's' && c != 'v' {
fmt.Fprintf(f, "{UNKNOWN FORMAT '%c'}", c)
return
}
// Precision is better in this case, because it allows
// specifying 0 padding easily.
padding, ok := f.Precision()
if !ok {
padding = 1
}
indent := strings.Repeat("\t", padding)
if f.Flag(' ') {
indent = strings.Repeat(" ", padding)
}
symPadding, ok := f.Width()
if !ok {
symPadding = padding - 1
}
if symPadding < 0 {
symPadding = 0
}
symIndent := strings.Repeat("\t", symPadding)
if f.Flag(' ') {
symIndent = strings.Repeat(" ", symPadding)
}
// Guess how many digits we need at most, by assuming that all instructions
// are double wide.
highestOffset := len(insns) * 2
offsetWidth := int(math.Ceil(math.Log10(float64(highestOffset))))
iter := insns.Iterate()
for iter.Next() {
if iter.Ins.Symbol != "" {
fmt.Fprintf(f, "%s%s:\n", symIndent, iter.Ins.Symbol)
}
fmt.Fprintf(f, "%s%*d: %v\n", indent, offsetWidth, iter.Offset, iter.Ins)
}
}
// Marshal encodes a BPF program into the kernel format.
func (insns Instructions) Marshal(w io.Writer, bo binary.ByteOrder) error {
for i, ins := range insns {
_, err := ins.Marshal(w, bo)
if err != nil {
return fmt.Errorf("instruction %d: %w", i, err)
}
}
return nil
}
// Tag calculates the kernel tag for a series of instructions.
//
// It mirrors bpf_prog_calc_tag in the kernel and so can be compared
// to ProgramInfo.Tag to figure out whether a loaded program matches
// certain instructions.
func (insns Instructions) Tag(bo binary.ByteOrder) (string, error) {
h := sha1.New()
for i, ins := range insns {
if ins.IsLoadFromMap() {
ins.Constant = 0
}
_, err := ins.Marshal(h, bo)
if err != nil {
return "", fmt.Errorf("instruction %d: %w", i, err)
}
}
return hex.EncodeToString(h.Sum(nil)[:unix.BPF_TAG_SIZE]), nil
}
// Iterate allows iterating a BPF program while keeping track of
// various offsets.
//
// Modifying the instruction slice will lead to undefined behaviour.
func (insns Instructions) Iterate() *InstructionIterator {
return &InstructionIterator{insns: insns}
}
// InstructionIterator iterates over a BPF program.
type InstructionIterator struct {
insns Instructions
// The instruction in question.
Ins *Instruction
// The index of the instruction in the original instruction slice.
Index int
// The offset of the instruction in raw BPF instructions. This accounts
// for double-wide instructions.
Offset RawInstructionOffset
}
// Next returns true as long as there are any instructions remaining.
func (iter *InstructionIterator) Next() bool {
if len(iter.insns) == 0 {
return false
}
if iter.Ins != nil {
iter.Index++
iter.Offset += RawInstructionOffset(iter.Ins.OpCode.rawInstructions())
}
iter.Ins = &iter.insns[0]
iter.insns = iter.insns[1:]
return true
}
type bpfInstruction struct {
OpCode OpCode
Registers bpfRegisters
Offset int16
Constant int32
}
type bpfRegisters uint8
func newBPFRegisters(dst, src Register, bo binary.ByteOrder) (bpfRegisters, error) {
switch bo {
case binary.LittleEndian:
return bpfRegisters((src << 4) | (dst & 0xF)), nil
case binary.BigEndian:
return bpfRegisters((dst << 4) | (src & 0xF)), nil
default:
return 0, fmt.Errorf("unrecognized ByteOrder %T", bo)
}
}
func (r bpfRegisters) Unmarshal(bo binary.ByteOrder) (dst, src Register, err error) {
switch bo {
case binary.LittleEndian:
return Register(r & 0xF), Register(r >> 4), nil
case binary.BigEndian:
return Register(r >> 4), Register(r & 0xf), nil
default:
return 0, 0, fmt.Errorf("unrecognized ByteOrder %T", bo)
}
}
type unreferencedSymbolError struct {
symbol string
}
func (use *unreferencedSymbolError) Error() string {
return fmt.Sprintf("unreferenced symbol %s", use.symbol)
}
// IsUnreferencedSymbol returns true if err was caused by
// an unreferenced symbol.
func IsUnreferencedSymbol(err error) bool {
_, ok := err.(*unreferencedSymbolError)
return ok
}