mirror of
https://github.com/go-gitea/gitea
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d2ea21d0d8
* use certmagic for more extensible/robust ACME cert handling * accept TOS based on config option Signed-off-by: Andrew Thornton <art27@cantab.net> Co-authored-by: zeripath <art27@cantab.net> Co-authored-by: Lauris BH <lauris@nix.lv>
727 lines
18 KiB
Go
Vendored
727 lines
18 KiB
Go
Vendored
// Copyright 2016 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package bpf
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import "fmt"
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// An Instruction is one instruction executed by the BPF virtual
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// machine.
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type Instruction interface {
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// Assemble assembles the Instruction into a RawInstruction.
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Assemble() (RawInstruction, error)
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}
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// A RawInstruction is a raw BPF virtual machine instruction.
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type RawInstruction struct {
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// Operation to execute.
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Op uint16
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// For conditional jump instructions, the number of instructions
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// to skip if the condition is true/false.
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Jt uint8
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Jf uint8
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// Constant parameter. The meaning depends on the Op.
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K uint32
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}
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// Assemble implements the Instruction Assemble method.
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func (ri RawInstruction) Assemble() (RawInstruction, error) { return ri, nil }
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// Disassemble parses ri into an Instruction and returns it. If ri is
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// not recognized by this package, ri itself is returned.
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func (ri RawInstruction) Disassemble() Instruction {
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switch ri.Op & opMaskCls {
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case opClsLoadA, opClsLoadX:
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reg := Register(ri.Op & opMaskLoadDest)
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sz := 0
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switch ri.Op & opMaskLoadWidth {
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case opLoadWidth4:
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sz = 4
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case opLoadWidth2:
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sz = 2
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case opLoadWidth1:
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sz = 1
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default:
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return ri
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}
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switch ri.Op & opMaskLoadMode {
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case opAddrModeImmediate:
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if sz != 4 {
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return ri
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}
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return LoadConstant{Dst: reg, Val: ri.K}
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case opAddrModeScratch:
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if sz != 4 || ri.K > 15 {
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return ri
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}
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return LoadScratch{Dst: reg, N: int(ri.K)}
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case opAddrModeAbsolute:
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if ri.K > extOffset+0xffffffff {
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return LoadExtension{Num: Extension(-extOffset + ri.K)}
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}
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return LoadAbsolute{Size: sz, Off: ri.K}
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case opAddrModeIndirect:
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return LoadIndirect{Size: sz, Off: ri.K}
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case opAddrModePacketLen:
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if sz != 4 {
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return ri
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}
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return LoadExtension{Num: ExtLen}
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case opAddrModeMemShift:
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return LoadMemShift{Off: ri.K}
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default:
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return ri
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}
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case opClsStoreA:
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if ri.Op != opClsStoreA || ri.K > 15 {
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return ri
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}
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return StoreScratch{Src: RegA, N: int(ri.K)}
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case opClsStoreX:
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if ri.Op != opClsStoreX || ri.K > 15 {
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return ri
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}
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return StoreScratch{Src: RegX, N: int(ri.K)}
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case opClsALU:
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switch op := ALUOp(ri.Op & opMaskOperator); op {
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case ALUOpAdd, ALUOpSub, ALUOpMul, ALUOpDiv, ALUOpOr, ALUOpAnd, ALUOpShiftLeft, ALUOpShiftRight, ALUOpMod, ALUOpXor:
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switch operand := opOperand(ri.Op & opMaskOperand); operand {
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case opOperandX:
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return ALUOpX{Op: op}
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case opOperandConstant:
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return ALUOpConstant{Op: op, Val: ri.K}
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default:
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return ri
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}
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case aluOpNeg:
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return NegateA{}
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default:
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return ri
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}
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case opClsJump:
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switch op := jumpOp(ri.Op & opMaskOperator); op {
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case opJumpAlways:
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return Jump{Skip: ri.K}
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case opJumpEqual, opJumpGT, opJumpGE, opJumpSet:
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cond, skipTrue, skipFalse := jumpOpToTest(op, ri.Jt, ri.Jf)
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switch operand := opOperand(ri.Op & opMaskOperand); operand {
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case opOperandX:
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return JumpIfX{Cond: cond, SkipTrue: skipTrue, SkipFalse: skipFalse}
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case opOperandConstant:
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return JumpIf{Cond: cond, Val: ri.K, SkipTrue: skipTrue, SkipFalse: skipFalse}
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default:
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return ri
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}
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default:
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return ri
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}
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case opClsReturn:
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switch ri.Op {
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case opClsReturn | opRetSrcA:
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return RetA{}
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case opClsReturn | opRetSrcConstant:
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return RetConstant{Val: ri.K}
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default:
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return ri
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}
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case opClsMisc:
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switch ri.Op {
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case opClsMisc | opMiscTAX:
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return TAX{}
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case opClsMisc | opMiscTXA:
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return TXA{}
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default:
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return ri
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}
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default:
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panic("unreachable") // switch is exhaustive on the bit pattern
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}
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}
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func jumpOpToTest(op jumpOp, skipTrue uint8, skipFalse uint8) (JumpTest, uint8, uint8) {
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var test JumpTest
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// Decode "fake" jump conditions that don't appear in machine code
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// Ensures the Assemble -> Disassemble stage recreates the same instructions
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// See https://github.com/golang/go/issues/18470
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if skipTrue == 0 {
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switch op {
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case opJumpEqual:
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test = JumpNotEqual
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case opJumpGT:
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test = JumpLessOrEqual
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case opJumpGE:
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test = JumpLessThan
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case opJumpSet:
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test = JumpBitsNotSet
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}
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return test, skipFalse, 0
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}
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switch op {
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case opJumpEqual:
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test = JumpEqual
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case opJumpGT:
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test = JumpGreaterThan
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case opJumpGE:
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test = JumpGreaterOrEqual
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case opJumpSet:
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test = JumpBitsSet
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}
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return test, skipTrue, skipFalse
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}
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// LoadConstant loads Val into register Dst.
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type LoadConstant struct {
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Dst Register
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Val uint32
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}
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// Assemble implements the Instruction Assemble method.
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func (a LoadConstant) Assemble() (RawInstruction, error) {
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return assembleLoad(a.Dst, 4, opAddrModeImmediate, a.Val)
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}
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// String returns the instruction in assembler notation.
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func (a LoadConstant) String() string {
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switch a.Dst {
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case RegA:
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return fmt.Sprintf("ld #%d", a.Val)
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case RegX:
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return fmt.Sprintf("ldx #%d", a.Val)
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// LoadScratch loads scratch[N] into register Dst.
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type LoadScratch struct {
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Dst Register
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N int // 0-15
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}
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// Assemble implements the Instruction Assemble method.
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func (a LoadScratch) Assemble() (RawInstruction, error) {
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if a.N < 0 || a.N > 15 {
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return RawInstruction{}, fmt.Errorf("invalid scratch slot %d", a.N)
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}
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return assembleLoad(a.Dst, 4, opAddrModeScratch, uint32(a.N))
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}
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// String returns the instruction in assembler notation.
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func (a LoadScratch) String() string {
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switch a.Dst {
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case RegA:
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return fmt.Sprintf("ld M[%d]", a.N)
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case RegX:
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return fmt.Sprintf("ldx M[%d]", a.N)
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// LoadAbsolute loads packet[Off:Off+Size] as an integer value into
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// register A.
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type LoadAbsolute struct {
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Off uint32
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Size int // 1, 2 or 4
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}
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// Assemble implements the Instruction Assemble method.
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func (a LoadAbsolute) Assemble() (RawInstruction, error) {
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return assembleLoad(RegA, a.Size, opAddrModeAbsolute, a.Off)
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}
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// String returns the instruction in assembler notation.
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func (a LoadAbsolute) String() string {
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switch a.Size {
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case 1: // byte
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return fmt.Sprintf("ldb [%d]", a.Off)
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case 2: // half word
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return fmt.Sprintf("ldh [%d]", a.Off)
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case 4: // word
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if a.Off > extOffset+0xffffffff {
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return LoadExtension{Num: Extension(a.Off + 0x1000)}.String()
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}
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return fmt.Sprintf("ld [%d]", a.Off)
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// LoadIndirect loads packet[X+Off:X+Off+Size] as an integer value
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// into register A.
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type LoadIndirect struct {
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Off uint32
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Size int // 1, 2 or 4
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}
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// Assemble implements the Instruction Assemble method.
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func (a LoadIndirect) Assemble() (RawInstruction, error) {
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return assembleLoad(RegA, a.Size, opAddrModeIndirect, a.Off)
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}
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// String returns the instruction in assembler notation.
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func (a LoadIndirect) String() string {
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switch a.Size {
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case 1: // byte
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return fmt.Sprintf("ldb [x + %d]", a.Off)
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case 2: // half word
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return fmt.Sprintf("ldh [x + %d]", a.Off)
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case 4: // word
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return fmt.Sprintf("ld [x + %d]", a.Off)
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// LoadMemShift multiplies the first 4 bits of the byte at packet[Off]
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// by 4 and stores the result in register X.
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//
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// This instruction is mainly useful to load into X the length of an
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// IPv4 packet header in a single instruction, rather than have to do
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// the arithmetic on the header's first byte by hand.
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type LoadMemShift struct {
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Off uint32
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}
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// Assemble implements the Instruction Assemble method.
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func (a LoadMemShift) Assemble() (RawInstruction, error) {
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return assembleLoad(RegX, 1, opAddrModeMemShift, a.Off)
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}
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// String returns the instruction in assembler notation.
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func (a LoadMemShift) String() string {
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return fmt.Sprintf("ldx 4*([%d]&0xf)", a.Off)
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}
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// LoadExtension invokes a linux-specific extension and stores the
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// result in register A.
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type LoadExtension struct {
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Num Extension
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}
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// Assemble implements the Instruction Assemble method.
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func (a LoadExtension) Assemble() (RawInstruction, error) {
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if a.Num == ExtLen {
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return assembleLoad(RegA, 4, opAddrModePacketLen, 0)
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}
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return assembleLoad(RegA, 4, opAddrModeAbsolute, uint32(extOffset+a.Num))
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}
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// String returns the instruction in assembler notation.
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func (a LoadExtension) String() string {
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switch a.Num {
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case ExtLen:
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return "ld #len"
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case ExtProto:
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return "ld #proto"
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case ExtType:
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return "ld #type"
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case ExtPayloadOffset:
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return "ld #poff"
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case ExtInterfaceIndex:
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return "ld #ifidx"
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case ExtNetlinkAttr:
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return "ld #nla"
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case ExtNetlinkAttrNested:
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return "ld #nlan"
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case ExtMark:
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return "ld #mark"
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case ExtQueue:
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return "ld #queue"
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case ExtLinkLayerType:
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return "ld #hatype"
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case ExtRXHash:
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return "ld #rxhash"
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case ExtCPUID:
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return "ld #cpu"
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case ExtVLANTag:
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return "ld #vlan_tci"
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case ExtVLANTagPresent:
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return "ld #vlan_avail"
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case ExtVLANProto:
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return "ld #vlan_tpid"
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case ExtRand:
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return "ld #rand"
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// StoreScratch stores register Src into scratch[N].
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type StoreScratch struct {
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Src Register
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N int // 0-15
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}
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// Assemble implements the Instruction Assemble method.
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func (a StoreScratch) Assemble() (RawInstruction, error) {
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if a.N < 0 || a.N > 15 {
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return RawInstruction{}, fmt.Errorf("invalid scratch slot %d", a.N)
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}
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var op uint16
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switch a.Src {
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case RegA:
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op = opClsStoreA
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case RegX:
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op = opClsStoreX
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default:
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return RawInstruction{}, fmt.Errorf("invalid source register %v", a.Src)
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}
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return RawInstruction{
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Op: op,
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K: uint32(a.N),
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}, nil
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}
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// String returns the instruction in assembler notation.
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func (a StoreScratch) String() string {
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switch a.Src {
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case RegA:
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return fmt.Sprintf("st M[%d]", a.N)
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case RegX:
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return fmt.Sprintf("stx M[%d]", a.N)
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// ALUOpConstant executes A = A <Op> Val.
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type ALUOpConstant struct {
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Op ALUOp
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Val uint32
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}
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// Assemble implements the Instruction Assemble method.
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func (a ALUOpConstant) Assemble() (RawInstruction, error) {
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return RawInstruction{
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Op: opClsALU | uint16(opOperandConstant) | uint16(a.Op),
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K: a.Val,
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}, nil
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}
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// String returns the instruction in assembler notation.
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func (a ALUOpConstant) String() string {
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switch a.Op {
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case ALUOpAdd:
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return fmt.Sprintf("add #%d", a.Val)
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case ALUOpSub:
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return fmt.Sprintf("sub #%d", a.Val)
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case ALUOpMul:
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return fmt.Sprintf("mul #%d", a.Val)
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case ALUOpDiv:
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return fmt.Sprintf("div #%d", a.Val)
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case ALUOpMod:
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return fmt.Sprintf("mod #%d", a.Val)
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case ALUOpAnd:
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return fmt.Sprintf("and #%d", a.Val)
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case ALUOpOr:
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return fmt.Sprintf("or #%d", a.Val)
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case ALUOpXor:
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return fmt.Sprintf("xor #%d", a.Val)
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case ALUOpShiftLeft:
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return fmt.Sprintf("lsh #%d", a.Val)
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case ALUOpShiftRight:
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return fmt.Sprintf("rsh #%d", a.Val)
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// ALUOpX executes A = A <Op> X
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type ALUOpX struct {
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Op ALUOp
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}
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// Assemble implements the Instruction Assemble method.
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func (a ALUOpX) Assemble() (RawInstruction, error) {
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return RawInstruction{
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Op: opClsALU | uint16(opOperandX) | uint16(a.Op),
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}, nil
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}
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// String returns the instruction in assembler notation.
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func (a ALUOpX) String() string {
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switch a.Op {
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case ALUOpAdd:
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return "add x"
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case ALUOpSub:
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return "sub x"
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case ALUOpMul:
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return "mul x"
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case ALUOpDiv:
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return "div x"
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case ALUOpMod:
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return "mod x"
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case ALUOpAnd:
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return "and x"
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case ALUOpOr:
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return "or x"
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case ALUOpXor:
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return "xor x"
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case ALUOpShiftLeft:
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return "lsh x"
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case ALUOpShiftRight:
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return "rsh x"
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default:
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return fmt.Sprintf("unknown instruction: %#v", a)
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}
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}
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// NegateA executes A = -A.
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type NegateA struct{}
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// Assemble implements the Instruction Assemble method.
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func (a NegateA) Assemble() (RawInstruction, error) {
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return RawInstruction{
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Op: opClsALU | uint16(aluOpNeg),
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}, nil
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}
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// String returns the instruction in assembler notation.
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func (a NegateA) String() string {
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return fmt.Sprintf("neg")
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}
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// Jump skips the following Skip instructions in the program.
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type Jump struct {
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Skip uint32
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}
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// Assemble implements the Instruction Assemble method.
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func (a Jump) Assemble() (RawInstruction, error) {
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return RawInstruction{
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Op: opClsJump | uint16(opJumpAlways),
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K: a.Skip,
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}, nil
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}
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// String returns the instruction in assembler notation.
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func (a Jump) String() string {
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return fmt.Sprintf("ja %d", a.Skip)
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}
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// JumpIf skips the following Skip instructions in the program if A
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// <Cond> Val is true.
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type JumpIf struct {
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Cond JumpTest
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Val uint32
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SkipTrue uint8
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SkipFalse uint8
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}
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// Assemble implements the Instruction Assemble method.
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func (a JumpIf) Assemble() (RawInstruction, error) {
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return jumpToRaw(a.Cond, opOperandConstant, a.Val, a.SkipTrue, a.SkipFalse)
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}
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// String returns the instruction in assembler notation.
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func (a JumpIf) String() string {
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return jumpToString(a.Cond, fmt.Sprintf("#%d", a.Val), a.SkipTrue, a.SkipFalse)
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}
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// JumpIfX skips the following Skip instructions in the program if A
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// <Cond> X is true.
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type JumpIfX struct {
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Cond JumpTest
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SkipTrue uint8
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SkipFalse uint8
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}
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// Assemble implements the Instruction Assemble method.
|
|
func (a JumpIfX) Assemble() (RawInstruction, error) {
|
|
return jumpToRaw(a.Cond, opOperandX, 0, a.SkipTrue, a.SkipFalse)
|
|
}
|
|
|
|
// String returns the instruction in assembler notation.
|
|
func (a JumpIfX) String() string {
|
|
return jumpToString(a.Cond, "x", a.SkipTrue, a.SkipFalse)
|
|
}
|
|
|
|
// jumpToRaw assembles a jump instruction into a RawInstruction
|
|
func jumpToRaw(test JumpTest, operand opOperand, k uint32, skipTrue, skipFalse uint8) (RawInstruction, error) {
|
|
var (
|
|
cond jumpOp
|
|
flip bool
|
|
)
|
|
switch test {
|
|
case JumpEqual:
|
|
cond = opJumpEqual
|
|
case JumpNotEqual:
|
|
cond, flip = opJumpEqual, true
|
|
case JumpGreaterThan:
|
|
cond = opJumpGT
|
|
case JumpLessThan:
|
|
cond, flip = opJumpGE, true
|
|
case JumpGreaterOrEqual:
|
|
cond = opJumpGE
|
|
case JumpLessOrEqual:
|
|
cond, flip = opJumpGT, true
|
|
case JumpBitsSet:
|
|
cond = opJumpSet
|
|
case JumpBitsNotSet:
|
|
cond, flip = opJumpSet, true
|
|
default:
|
|
return RawInstruction{}, fmt.Errorf("unknown JumpTest %v", test)
|
|
}
|
|
jt, jf := skipTrue, skipFalse
|
|
if flip {
|
|
jt, jf = jf, jt
|
|
}
|
|
return RawInstruction{
|
|
Op: opClsJump | uint16(cond) | uint16(operand),
|
|
Jt: jt,
|
|
Jf: jf,
|
|
K: k,
|
|
}, nil
|
|
}
|
|
|
|
// jumpToString converts a jump instruction to assembler notation
|
|
func jumpToString(cond JumpTest, operand string, skipTrue, skipFalse uint8) string {
|
|
switch cond {
|
|
// K == A
|
|
case JumpEqual:
|
|
return conditionalJump(operand, skipTrue, skipFalse, "jeq", "jneq")
|
|
// K != A
|
|
case JumpNotEqual:
|
|
return fmt.Sprintf("jneq %s,%d", operand, skipTrue)
|
|
// K > A
|
|
case JumpGreaterThan:
|
|
return conditionalJump(operand, skipTrue, skipFalse, "jgt", "jle")
|
|
// K < A
|
|
case JumpLessThan:
|
|
return fmt.Sprintf("jlt %s,%d", operand, skipTrue)
|
|
// K >= A
|
|
case JumpGreaterOrEqual:
|
|
return conditionalJump(operand, skipTrue, skipFalse, "jge", "jlt")
|
|
// K <= A
|
|
case JumpLessOrEqual:
|
|
return fmt.Sprintf("jle %s,%d", operand, skipTrue)
|
|
// K & A != 0
|
|
case JumpBitsSet:
|
|
if skipFalse > 0 {
|
|
return fmt.Sprintf("jset %s,%d,%d", operand, skipTrue, skipFalse)
|
|
}
|
|
return fmt.Sprintf("jset %s,%d", operand, skipTrue)
|
|
// K & A == 0, there is no assembler instruction for JumpBitNotSet, use JumpBitSet and invert skips
|
|
case JumpBitsNotSet:
|
|
return jumpToString(JumpBitsSet, operand, skipFalse, skipTrue)
|
|
default:
|
|
return fmt.Sprintf("unknown JumpTest %#v", cond)
|
|
}
|
|
}
|
|
|
|
func conditionalJump(operand string, skipTrue, skipFalse uint8, positiveJump, negativeJump string) string {
|
|
if skipTrue > 0 {
|
|
if skipFalse > 0 {
|
|
return fmt.Sprintf("%s %s,%d,%d", positiveJump, operand, skipTrue, skipFalse)
|
|
}
|
|
return fmt.Sprintf("%s %s,%d", positiveJump, operand, skipTrue)
|
|
}
|
|
return fmt.Sprintf("%s %s,%d", negativeJump, operand, skipFalse)
|
|
}
|
|
|
|
// RetA exits the BPF program, returning the value of register A.
|
|
type RetA struct{}
|
|
|
|
// Assemble implements the Instruction Assemble method.
|
|
func (a RetA) Assemble() (RawInstruction, error) {
|
|
return RawInstruction{
|
|
Op: opClsReturn | opRetSrcA,
|
|
}, nil
|
|
}
|
|
|
|
// String returns the instruction in assembler notation.
|
|
func (a RetA) String() string {
|
|
return fmt.Sprintf("ret a")
|
|
}
|
|
|
|
// RetConstant exits the BPF program, returning a constant value.
|
|
type RetConstant struct {
|
|
Val uint32
|
|
}
|
|
|
|
// Assemble implements the Instruction Assemble method.
|
|
func (a RetConstant) Assemble() (RawInstruction, error) {
|
|
return RawInstruction{
|
|
Op: opClsReturn | opRetSrcConstant,
|
|
K: a.Val,
|
|
}, nil
|
|
}
|
|
|
|
// String returns the instruction in assembler notation.
|
|
func (a RetConstant) String() string {
|
|
return fmt.Sprintf("ret #%d", a.Val)
|
|
}
|
|
|
|
// TXA copies the value of register X to register A.
|
|
type TXA struct{}
|
|
|
|
// Assemble implements the Instruction Assemble method.
|
|
func (a TXA) Assemble() (RawInstruction, error) {
|
|
return RawInstruction{
|
|
Op: opClsMisc | opMiscTXA,
|
|
}, nil
|
|
}
|
|
|
|
// String returns the instruction in assembler notation.
|
|
func (a TXA) String() string {
|
|
return fmt.Sprintf("txa")
|
|
}
|
|
|
|
// TAX copies the value of register A to register X.
|
|
type TAX struct{}
|
|
|
|
// Assemble implements the Instruction Assemble method.
|
|
func (a TAX) Assemble() (RawInstruction, error) {
|
|
return RawInstruction{
|
|
Op: opClsMisc | opMiscTAX,
|
|
}, nil
|
|
}
|
|
|
|
// String returns the instruction in assembler notation.
|
|
func (a TAX) String() string {
|
|
return fmt.Sprintf("tax")
|
|
}
|
|
|
|
func assembleLoad(dst Register, loadSize int, mode uint16, k uint32) (RawInstruction, error) {
|
|
var (
|
|
cls uint16
|
|
sz uint16
|
|
)
|
|
switch dst {
|
|
case RegA:
|
|
cls = opClsLoadA
|
|
case RegX:
|
|
cls = opClsLoadX
|
|
default:
|
|
return RawInstruction{}, fmt.Errorf("invalid target register %v", dst)
|
|
}
|
|
switch loadSize {
|
|
case 1:
|
|
sz = opLoadWidth1
|
|
case 2:
|
|
sz = opLoadWidth2
|
|
case 4:
|
|
sz = opLoadWidth4
|
|
default:
|
|
return RawInstruction{}, fmt.Errorf("invalid load byte length %d", sz)
|
|
}
|
|
return RawInstruction{
|
|
Op: cls | sz | mode,
|
|
K: k,
|
|
}, nil
|
|
}
|