op-geth/transaction.go

181 lines
4.3 KiB
Go

package main
import (
"math/big"
"fmt"
"encoding/hex"
"crypto/sha256"
_ "bytes"
)
/*
Transaction Contract Size
-------------------------------------------
sender sender 20 bytes
recipient 0x0 20 bytes
value endowment 4 bytes (uint32)
fee fee 4 bytes (uint32)
d_size o_size 4 bytes (uint32)
data ops *
signature signature 64 bytes
*/
var StepFee *big.Int = new(big.Int)
var TxFee *big.Int = new(big.Int)
var ContractFee *big.Int = new(big.Int)
var MemFee *big.Int = new(big.Int)
var DataFee *big.Int = new(big.Int)
var CryptoFee *big.Int = new(big.Int)
var ExtroFee *big.Int = new(big.Int)
var Period1Reward *big.Int = new(big.Int)
var Period2Reward *big.Int = new(big.Int)
var Period3Reward *big.Int = new(big.Int)
var Period4Reward *big.Int = new(big.Int)
type Transaction struct {
sender string
recipient string
value uint32
fee uint32
data []string
memory []int
lastTx string
// To be removed
signature string
addr string
}
func NewTransaction(to string, value uint32, data []string) *Transaction {
tx := Transaction{sender: "1234567890", recipient: to, value: value}
tx.fee = 0//uint32((ContractFee + MemoryFee * float32(len(tx.data))) * 1e8)
tx.lastTx = "0"
// Serialize the data
tx.data = make([]string, len(data))
for i, val := range data {
instr, err := CompileInstr(val)
if err != nil {
fmt.Printf("compile error:%d %v", i+1, err)
}
tx.data[i] = instr
}
b:= []byte(tx.MarshalRlp())
hash := sha256.Sum256(b)
tx.addr = hex.EncodeToString(hash[0:19])
return &tx
}
func (tx *Transaction) MarshalRlp() []byte {
// Prepare the transaction for serialization
preEnc := []interface{}{
tx.lastTx,
tx.sender,
tx.recipient,
tx.value,
tx.fee,
tx.data,
}
return Encode(preEnc)
}
func (tx *Transaction) UnmarshalRlp(data []byte) {
t, _ := Decode(data,0)
if slice, ok := t.([]interface{}); ok {
if lastTx, ok := slice[0].([]byte); ok {
tx.lastTx = string(lastTx)
}
if sender, ok := slice[1].([]byte); ok {
tx.sender = string(sender)
}
if recipient, ok := slice[2].([]byte); ok {
tx.recipient = string(recipient)
}
// If only I knew of a better way.
if value, ok := slice[3].(uint8); ok {
tx.value = uint32(value)
}
if value, ok := slice[3].(uint16); ok {
tx.value = uint32(value)
}
if value, ok := slice[3].(uint32); ok {
tx.value = uint32(value)
}
if value, ok := slice[3].(uint64); ok {
tx.value = uint32(value)
}
if fee, ok := slice[4].(uint8); ok {
tx.fee = uint32(fee)
}
if fee, ok := slice[4].(uint16); ok {
tx.fee = uint32(fee)
}
if fee, ok := slice[4].(uint32); ok {
tx.fee = uint32(fee)
}
if fee, ok := slice[4].(uint64); ok {
tx.fee = uint32(fee)
}
// Encode the data/instructions
if data, ok := slice[5].([]interface{}); ok {
tx.data = make([]string, len(data))
for i, d := range data {
if instr, ok := d.([]byte); ok {
tx.data[i] = string(instr)
}
}
}
}
}
func InitFees() {
// Base for 2**60
b60 := new(big.Int)
b60.Exp(big.NewInt(2), big.NewInt(64), big.NewInt(0))
// Base for 2**80
b80 := new(big.Int)
b80.Exp(big.NewInt(2), big.NewInt(80), big.NewInt(0))
StepFee.Div(b60, big.NewInt(64))
//fmt.Println("StepFee:", StepFee)
TxFee.Exp(big.NewInt(2), big.NewInt(64), big.NewInt(0))
//fmt.Println("TxFee:", TxFee)
ContractFee.Exp(big.NewInt(2), big.NewInt(64), big.NewInt(0))
//fmt.Println("ContractFee:", ContractFee)
MemFee.Div(b60, big.NewInt(4))
//fmt.Println("MemFee:", MemFee)
DataFee.Div(b60, big.NewInt(16))
//fmt.Println("DataFee:", DataFee)
CryptoFee.Div(b60, big.NewInt(16))
//fmt.Println("CrytoFee:", CryptoFee)
ExtroFee.Div(b60, big.NewInt(16))
//fmt.Println("ExtroFee:", ExtroFee)
Period1Reward.Mul(b80, big.NewInt(1024))
//fmt.Println("Period1Reward:", Period1Reward)
Period2Reward.Mul(b80, big.NewInt(512))
//fmt.Println("Period2Reward:", Period2Reward)
Period3Reward.Mul(b80, big.NewInt(256))
//fmt.Println("Period3Reward:", Period3Reward)
Period4Reward.Mul(b80, big.NewInt(128))
//fmt.Println("Period4Reward:", Period4Reward)
}