package asm import ( "fmt" "strings" ) //go:generate stringer -output opcode_string.go -type=Class type encoding int const ( unknownEncoding encoding = iota loadOrStore jumpOrALU ) // Class of operations // // msb lsb // +---+--+---+ // | ?? |CLS| // +---+--+---+ type Class uint8 const classMask OpCode = 0x07 const ( // LdClass load memory LdClass Class = 0x00 // LdXClass load memory from constant LdXClass Class = 0x01 // StClass load register from memory StClass Class = 0x02 // StXClass load register from constant StXClass Class = 0x03 // ALUClass arithmetic operators ALUClass Class = 0x04 // JumpClass jump operators JumpClass Class = 0x05 // ALU64Class arithmetic in 64 bit mode ALU64Class Class = 0x07 ) func (cls Class) encoding() encoding { switch cls { case LdClass, LdXClass, StClass, StXClass: return loadOrStore case ALU64Class, ALUClass, JumpClass: return jumpOrALU default: return unknownEncoding } } // OpCode is a packed eBPF opcode. // // Its encoding is defined by a Class value: // // msb lsb // +----+-+---+ // | ???? |CLS| // +----+-+---+ type OpCode uint8 // InvalidOpCode is returned by setters on OpCode const InvalidOpCode OpCode = 0xff // rawInstructions returns the number of BPF instructions required // to encode this opcode. func (op OpCode) rawInstructions() int { if op.IsDWordLoad() { return 2 } return 1 } func (op OpCode) IsDWordLoad() bool { return op == LoadImmOp(DWord) } // Class returns the class of operation. func (op OpCode) Class() Class { return Class(op & classMask) } // Mode returns the mode for load and store operations. func (op OpCode) Mode() Mode { if op.Class().encoding() != loadOrStore { return InvalidMode } return Mode(op & modeMask) } // Size returns the size for load and store operations. func (op OpCode) Size() Size { if op.Class().encoding() != loadOrStore { return InvalidSize } return Size(op & sizeMask) } // Source returns the source for branch and ALU operations. func (op OpCode) Source() Source { if op.Class().encoding() != jumpOrALU || op.ALUOp() == Swap { return InvalidSource } return Source(op & sourceMask) } // ALUOp returns the ALUOp. func (op OpCode) ALUOp() ALUOp { if op.Class().encoding() != jumpOrALU { return InvalidALUOp } return ALUOp(op & aluMask) } // Endianness returns the Endianness for a byte swap instruction. func (op OpCode) Endianness() Endianness { if op.ALUOp() != Swap { return InvalidEndian } return Endianness(op & endianMask) } // JumpOp returns the JumpOp. func (op OpCode) JumpOp() JumpOp { if op.Class().encoding() != jumpOrALU { return InvalidJumpOp } return JumpOp(op & jumpMask) } // SetMode sets the mode on load and store operations. // // Returns InvalidOpCode if op is of the wrong class. func (op OpCode) SetMode(mode Mode) OpCode { if op.Class().encoding() != loadOrStore || !valid(OpCode(mode), modeMask) { return InvalidOpCode } return (op & ^modeMask) | OpCode(mode) } // SetSize sets the size on load and store operations. // // Returns InvalidOpCode if op is of the wrong class. func (op OpCode) SetSize(size Size) OpCode { if op.Class().encoding() != loadOrStore || !valid(OpCode(size), sizeMask) { return InvalidOpCode } return (op & ^sizeMask) | OpCode(size) } // SetSource sets the source on jump and ALU operations. // // Returns InvalidOpCode if op is of the wrong class. func (op OpCode) SetSource(source Source) OpCode { if op.Class().encoding() != jumpOrALU || !valid(OpCode(source), sourceMask) { return InvalidOpCode } return (op & ^sourceMask) | OpCode(source) } // SetALUOp sets the ALUOp on ALU operations. // // Returns InvalidOpCode if op is of the wrong class. func (op OpCode) SetALUOp(alu ALUOp) OpCode { class := op.Class() if (class != ALUClass && class != ALU64Class) || !valid(OpCode(alu), aluMask) { return InvalidOpCode } return (op & ^aluMask) | OpCode(alu) } // SetJumpOp sets the JumpOp on jump operations. // // Returns InvalidOpCode if op is of the wrong class. func (op OpCode) SetJumpOp(jump JumpOp) OpCode { if op.Class() != JumpClass || !valid(OpCode(jump), jumpMask) { return InvalidOpCode } return (op & ^jumpMask) | OpCode(jump) } func (op OpCode) String() string { var f strings.Builder switch class := op.Class(); class { case LdClass, LdXClass, StClass, StXClass: f.WriteString(strings.TrimSuffix(class.String(), "Class")) mode := op.Mode() f.WriteString(strings.TrimSuffix(mode.String(), "Mode")) switch op.Size() { case DWord: f.WriteString("DW") case Word: f.WriteString("W") case Half: f.WriteString("H") case Byte: f.WriteString("B") } case ALU64Class, ALUClass: f.WriteString(op.ALUOp().String()) if op.ALUOp() == Swap { // Width for Endian is controlled by Constant f.WriteString(op.Endianness().String()) } else { if class == ALUClass { f.WriteString("32") } f.WriteString(strings.TrimSuffix(op.Source().String(), "Source")) } case JumpClass: f.WriteString(op.JumpOp().String()) if jop := op.JumpOp(); jop != Exit && jop != Call { f.WriteString(strings.TrimSuffix(op.Source().String(), "Source")) } default: fmt.Fprintf(&f, "OpCode(%#x)", uint8(op)) } return f.String() } // valid returns true if all bits in value are covered by mask. func valid(value, mask OpCode) bool { return value & ^mask == 0 }