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forgejo/vendor/github.com/nwaples/rardecode/vm.go

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package rardecode
import (
"encoding/binary"
"errors"
)
const (
// vm flag bits
flagC = 1 // Carry
flagZ = 2 // Zero
flagS = 0x80000000 // Sign
maxCommands = 25000000 // maximum number of commands that can be run in a program
vmRegs = 8 // number if registers
vmSize = 0x40000 // memory size
vmMask = vmSize - 1
)
var (
errInvalidVMInstruction = errors.New("rardecode: invalid vm instruction")
)
type vm struct {
ip uint32 // instruction pointer
ipMod bool // ip was modified
fl uint32 // flag bits
r [vmRegs]uint32 // registers
m []byte // memory
}
func (v *vm) setIP(ip uint32) {
v.ip = ip
v.ipMod = true
}
// execute runs a list of commands on the vm.
func (v *vm) execute(cmd []command) {
v.ip = 0 // reset instruction pointer
for n := 0; n < maxCommands; n++ {
ip := v.ip
if ip >= uint32(len(cmd)) {
return
}
ins := cmd[ip]
ins.f(v, ins.bm, ins.op) // run cpu instruction
if v.ipMod {
// command modified ip, don't increment
v.ipMod = false
} else {
v.ip++ // increment ip for next command
}
}
}
// newVM creates a new RAR virtual machine using the byte slice as memory.
func newVM(mem []byte) *vm {
v := new(vm)
if cap(mem) < vmSize+4 {
v.m = make([]byte, vmSize+4)
copy(v.m, mem)
} else {
v.m = mem[:vmSize+4]
for i := len(mem); i < len(v.m); i++ {
v.m[i] = 0
}
}
v.r[7] = vmSize
return v
}
type operand interface {
get(v *vm, byteMode bool) uint32
set(v *vm, byteMode bool, n uint32)
}
// Immediate Operand
type opI uint32
func (op opI) get(v *vm, bm bool) uint32 { return uint32(op) }
func (op opI) set(v *vm, bm bool, n uint32) {}
// Direct Operand
type opD uint32
func (op opD) get(v *vm, byteMode bool) uint32 {
if byteMode {
return uint32(v.m[op])
}
return binary.LittleEndian.Uint32(v.m[op:])
}
func (op opD) set(v *vm, byteMode bool, n uint32) {
if byteMode {
v.m[op] = byte(n)
} else {
binary.LittleEndian.PutUint32(v.m[op:], n)
}
}
// Register Operand
type opR uint32
func (op opR) get(v *vm, byteMode bool) uint32 {
if byteMode {
return v.r[op] & 0xFF
}
return v.r[op]
}
func (op opR) set(v *vm, byteMode bool, n uint32) {
if byteMode {
v.r[op] = (v.r[op] & 0xFFFFFF00) | (n & 0xFF)
} else {
v.r[op] = n
}
}
// Register Indirect Operand
type opRI uint32
func (op opRI) get(v *vm, byteMode bool) uint32 {
i := v.r[op] & vmMask
if byteMode {
return uint32(v.m[i])
}
return binary.LittleEndian.Uint32(v.m[i:])
}
func (op opRI) set(v *vm, byteMode bool, n uint32) {
i := v.r[op] & vmMask
if byteMode {
v.m[i] = byte(n)
} else {
binary.LittleEndian.PutUint32(v.m[i:], n)
}
}
// Base Plus Index Indirect Operand
type opBI struct {
r uint32
i uint32
}
func (op opBI) get(v *vm, byteMode bool) uint32 {
i := (v.r[op.r] + op.i) & vmMask
if byteMode {
return uint32(v.m[i])
}
return binary.LittleEndian.Uint32(v.m[i:])
}
func (op opBI) set(v *vm, byteMode bool, n uint32) {
i := (v.r[op.r] + op.i) & vmMask
if byteMode {
v.m[i] = byte(n)
} else {
binary.LittleEndian.PutUint32(v.m[i:], n)
}
}
type commandFunc func(v *vm, byteMode bool, op []operand)
type command struct {
f commandFunc
bm bool // is byte mode
op []operand
}
var (
ops = []struct {
f commandFunc
byteMode bool // supports byte mode
nops int // number of operands
jop bool // is a jump op
}{
{mov, true, 2, false},
{cmp, true, 2, false},
{add, true, 2, false},
{sub, true, 2, false},
{jz, false, 1, true},
{jnz, false, 1, true},
{inc, true, 1, false},
{dec, true, 1, false},
{jmp, false, 1, true},
{xor, true, 2, false},
{and, true, 2, false},
{or, true, 2, false},
{test, true, 2, false},
{js, false, 1, true},
{jns, false, 1, true},
{jb, false, 1, true},
{jbe, false, 1, true},
{ja, false, 1, true},
{jae, false, 1, true},
{push, false, 1, false},
{pop, false, 1, false},
{call, false, 1, true},
{ret, false, 0, false},
{not, true, 1, false},
{shl, true, 2, false},
{shr, true, 2, false},
{sar, true, 2, false},
{neg, true, 1, false},
{pusha, false, 0, false},
{popa, false, 0, false},
{pushf, false, 0, false},
{popf, false, 0, false},
{movzx, false, 2, false},
{movsx, false, 2, false},
{xchg, true, 2, false},
{mul, true, 2, false},
{div, true, 2, false},
{adc, true, 2, false},
{sbb, true, 2, false},
{print, false, 0, false},
}
)
func mov(v *vm, bm bool, op []operand) {
op[0].set(v, bm, op[1].get(v, bm))
}
func cmp(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
r := v1 - op[1].get(v, bm)
if r == 0 {
v.fl = flagZ
} else {
v.fl = 0
if r > v1 {
v.fl = flagC
}
v.fl |= r & flagS
}
}
func add(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
r := v1 + op[1].get(v, bm)
v.fl = 0
signBit := uint32(flagS)
if bm {
r &= 0xFF
signBit = 0x80
}
if r < v1 {
v.fl |= flagC
}
if r == 0 {
v.fl |= flagZ
} else if r&signBit > 0 {
v.fl |= flagS
}
op[0].set(v, bm, r)
}
func sub(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
r := v1 - op[1].get(v, bm)
v.fl = 0
if r == 0 {
v.fl = flagZ
} else {
v.fl = 0
if r > v1 {
v.fl = flagC
}
v.fl |= r & flagS
}
op[0].set(v, bm, r)
}
func jz(v *vm, bm bool, op []operand) {
if v.fl&flagZ > 0 {
v.setIP(op[0].get(v, false))
}
}
func jnz(v *vm, bm bool, op []operand) {
if v.fl&flagZ == 0 {
v.setIP(op[0].get(v, false))
}
}
func inc(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) + 1
if bm {
r &= 0xFF
}
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
}
func dec(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) - 1
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
}
func jmp(v *vm, bm bool, op []operand) {
v.setIP(op[0].get(v, false))
}
func xor(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) ^ op[1].get(v, bm)
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
}
func and(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) & op[1].get(v, bm)
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
}
func or(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) | op[1].get(v, bm)
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
}
func test(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) & op[1].get(v, bm)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
}
func js(v *vm, bm bool, op []operand) {
if v.fl&flagS > 0 {
v.setIP(op[0].get(v, false))
}
}
func jns(v *vm, bm bool, op []operand) {
if v.fl&flagS == 0 {
v.setIP(op[0].get(v, false))
}
}
func jb(v *vm, bm bool, op []operand) {
if v.fl&flagC > 0 {
v.setIP(op[0].get(v, false))
}
}
func jbe(v *vm, bm bool, op []operand) {
if v.fl&(flagC|flagZ) > 0 {
v.setIP(op[0].get(v, false))
}
}
func ja(v *vm, bm bool, op []operand) {
if v.fl&(flagC|flagZ) == 0 {
v.setIP(op[0].get(v, false))
}
}
func jae(v *vm, bm bool, op []operand) {
if v.fl&flagC == 0 {
v.setIP(op[0].get(v, false))
}
}
func push(v *vm, bm bool, op []operand) {
v.r[7] -= 4
opRI(7).set(v, false, op[0].get(v, false))
}
func pop(v *vm, bm bool, op []operand) {
op[0].set(v, false, opRI(7).get(v, false))
v.r[7] += 4
}
func call(v *vm, bm bool, op []operand) {
v.r[7] -= 4
opRI(7).set(v, false, v.ip+1)
v.setIP(op[0].get(v, false))
}
func ret(v *vm, bm bool, op []operand) {
r7 := v.r[7]
if r7 >= vmSize {
v.setIP(0xFFFFFFFF) // trigger end of program
} else {
v.setIP(binary.LittleEndian.Uint32(v.m[r7:]))
v.r[7] += 4
}
}
func not(v *vm, bm bool, op []operand) {
op[0].set(v, bm, ^op[0].get(v, bm))
}
func shl(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
v2 := op[1].get(v, bm)
r := v1 << v2
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
if (v1<<(v2-1))&0x80000000 > 0 {
v.fl |= flagC
}
}
func shr(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
v2 := op[1].get(v, bm)
r := v1 >> v2
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
if (v1>>(v2-1))&0x1 > 0 {
v.fl |= flagC
}
}
func sar(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
v2 := op[1].get(v, bm)
r := uint32(int32(v1) >> v2)
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
if (v1>>(v2-1))&0x1 > 0 {
v.fl |= flagC
}
}
func neg(v *vm, bm bool, op []operand) {
r := 0 - op[0].get(v, bm)
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r&flagS | flagC
}
}
func pusha(v *vm, bm bool, op []operand) {
sp := opD(v.r[7])
for _, r := range v.r {
sp = (sp - 4) & vmMask
sp.set(v, false, r)
}
v.r[7] = uint32(sp)
}
func popa(v *vm, bm bool, op []operand) {
sp := opD(v.r[7])
for i := 7; i >= 0; i-- {
v.r[i] = sp.get(v, false)
sp = (sp + 4) & vmMask
}
}
func pushf(v *vm, bm bool, op []operand) {
v.r[7] -= 4
opRI(7).set(v, false, v.fl)
}
func popf(v *vm, bm bool, op []operand) {
v.fl = opRI(7).get(v, false)
v.r[7] += 4
}
func movzx(v *vm, bm bool, op []operand) {
op[0].set(v, false, op[1].get(v, true))
}
func movsx(v *vm, bm bool, op []operand) {
op[0].set(v, false, uint32(int8(op[1].get(v, true))))
}
func xchg(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
op[0].set(v, bm, op[1].get(v, bm))
op[1].set(v, bm, v1)
}
func mul(v *vm, bm bool, op []operand) {
r := op[0].get(v, bm) * op[1].get(v, bm)
op[0].set(v, bm, r)
}
func div(v *vm, bm bool, op []operand) {
div := op[1].get(v, bm)
if div != 0 {
r := op[0].get(v, bm) / div
op[0].set(v, bm, r)
}
}
func adc(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
fc := v.fl & flagC
r := v1 + op[1].get(v, bm) + fc
if bm {
r &= 0xFF
}
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
if r < v1 || (r == v1 && fc > 0) {
v.fl |= flagC
}
}
func sbb(v *vm, bm bool, op []operand) {
v1 := op[0].get(v, bm)
fc := v.fl & flagC
r := v1 - op[1].get(v, bm) - fc
if bm {
r &= 0xFF
}
op[0].set(v, bm, r)
if r == 0 {
v.fl = flagZ
} else {
v.fl = r & flagS
}
if r > v1 || (r == v1 && fc > 0) {
v.fl |= flagC
}
}
func print(v *vm, bm bool, op []operand) {
// TODO: ignore print for the moment
}
func decodeArg(br *rarBitReader, byteMode bool) (operand, error) {
n, err := br.readBits(1)
if err != nil {
return nil, err
}
if n > 0 { // Register
n, err = br.readBits(3)
return opR(n), err
}
n, err = br.readBits(1)
if err != nil {
return nil, err
}
if n == 0 { // Immediate
if byteMode {
n, err = br.readBits(8)
} else {
m, err := br.readUint32()
return opI(m), err
}
return opI(n), err
}
n, err = br.readBits(1)
if err != nil {
return nil, err
}
if n == 0 {
// Register Indirect
n, err = br.readBits(3)
return opRI(n), err
}
n, err = br.readBits(1)
if err != nil {
return nil, err
}
if n == 0 {
// Base + Index Indirect
n, err = br.readBits(3)
if err != nil {
return nil, err
}
i, err := br.readUint32()
return opBI{r: uint32(n), i: i}, err
}
// Direct addressing
m, err := br.readUint32()
return opD(m & vmMask), err
}
func fixJumpOp(op operand, off int) operand {
n, ok := op.(opI)
if !ok {
return op
}
if n >= 256 {
return n - 256
}
if n >= 136 {
n -= 264
} else if n >= 16 {
n -= 8
} else if n >= 8 {
n -= 16
}
return n + opI(off)
}
func readCommands(br *rarBitReader) ([]command, error) {
var cmds []command
for {
code, err := br.readBits(4)
if err != nil {
return cmds, err
}
if code&0x08 > 0 {
n, err := br.readBits(2)
if err != nil {
return cmds, err
}
code = (code<<2 | n) - 24
}
if code >= len(ops) {
return cmds, errInvalidVMInstruction
}
ins := ops[code]
var com command
if ins.byteMode {
n, err := br.readBits(1)
if err != nil {
return cmds, err
}
com.bm = n > 0
}
com.f = ins.f
if ins.nops > 0 {
com.op = make([]operand, ins.nops)
com.op[0], err = decodeArg(br, com.bm)
if err != nil {
return cmds, err
}
if ins.nops == 2 {
com.op[1], err = decodeArg(br, com.bm)
if err != nil {
return cmds, err
}
} else if ins.jop {
com.op[0] = fixJumpOp(com.op[0], len(cmds))
}
}
cmds = append(cmds, com)
}
}