neo-go/pkg/vm/context.go
Roman Khimov 5bd666b786 vm: return NOP as current instruction for just loaded VM
Before:
NEO-GO-VM > loadgo h.go
READY: loaded 16 instructions
NEO-GO-VM > ip
instruction pointer at -1 (PUSH0)

After:
NEO-GO-VM > loadgo h.go
READY: loaded 16 instructions
NEO-GO-VM > ip
instruction pointer at -1 (NOP)

I think NOP is a little less scary.
2019-09-10 23:31:06 +03:00

128 lines
2.3 KiB
Go

package vm
import (
"encoding/binary"
)
// Context represent the current execution context of the VM.
type Context struct {
// Instruction pointer.
ip int
// The raw program script.
prog []byte
// Breakpoints
breakPoints []int
}
// NewContext return a new Context object.
func NewContext(b []byte) *Context {
return &Context{
ip: -1,
prog: b,
breakPoints: []int{},
}
}
// Next return the next instruction to execute.
func (c *Context) Next() Instruction {
c.ip++
if c.ip >= len(c.prog) {
return RET
}
return Instruction(c.prog[c.ip])
}
// IP returns the absolute instruction without taking 0 into account.
// If that program starts the ip = 0 but IP() will return 1, cause its
// the first instruction.
func (c *Context) IP() int {
return c.ip + 1
}
// LenInstr returns the number of instructions loaded.
func (c *Context) LenInstr() int {
return len(c.prog)
}
// CurrInstr returns the current instruction and opcode.
func (c *Context) CurrInstr() (int, Instruction) {
if c.ip < 0 {
return c.ip, NOP
}
return c.ip, Instruction(c.prog[c.ip])
}
// Copy returns an new exact copy of c.
func (c *Context) Copy() *Context {
return &Context{
ip: c.ip,
prog: c.prog,
breakPoints: c.breakPoints,
}
}
// Program returns the loaded program.
func (c *Context) Program() []byte {
return c.prog
}
// Value implements StackItem interface.
func (c *Context) Value() interface{} {
return c
}
func (c *Context) atBreakPoint() bool {
for _, n := range c.breakPoints {
if n == c.ip {
return true
}
}
return false
}
func (c *Context) String() string {
return "execution context"
}
func (c *Context) readUint32() uint32 {
start, end := c.IP(), c.IP()+4
if end > len(c.prog) {
return 0
}
val := binary.LittleEndian.Uint32(c.prog[start:end])
c.ip += 4
return val
}
func (c *Context) readUint16() uint16 {
start, end := c.IP(), c.IP()+2
if end > len(c.prog) {
return 0
}
val := binary.LittleEndian.Uint16(c.prog[start:end])
c.ip += 2
return val
}
func (c *Context) readByte() byte {
return c.readBytes(1)[0]
}
func (c *Context) readBytes(n int) []byte {
start, end := c.IP(), c.IP()+n
if end > len(c.prog) {
return nil
}
out := make([]byte, n)
copy(out, c.prog[start:end])
c.ip += n
return out
}
func (c *Context) readVarBytes() []byte {
n := c.readByte()
return c.readBytes(int(n))
}