//EquationTolist convert string to linkedlsit
func EquationToList(m string) *LinkedList.LinkedList {
l := LinkedList.NewLinkedList()
fmt.Println(m)
sg := strings.Split(m, "+")
f:
for _, v := range sg {
var node [2]int
var err error
if !strings.Contains(v, "x") {
node[0], _ = strconv.Atoi(v)
node[1] = 0
n := LinkedList.NewNode(node, nil)
l.Insert(*n)
continue f
}
tmp := strings.Split(v, "x")
node[0], err = strconv.Atoi(tmp[0])
if err != nil {
node[0] = 1
}
if strings.Contains(tmp[1], "^") {
node[1], _ = strconv.Atoi(string([]byte(tmp[1])[1:]))
} else {
node[1] = 1
}
n := LinkedList.NewNode(node, nil)
l.Insert(*n)
}
return l
}
func PolyAdd(l1, l2 *LinkedList.LinkedList) *LinkedList.LinkedList {
l := LinkedList.NewLinkedList()
n1 := l1.Head
n2 := l2.Head
for n1 != nil || n2 != nil {
if n1 != nil && (n2 == nil || getData(n1, 1) > getData(n2, 1)) {
n := LinkedList.NewNode(n1.Data, nil)
l.Insert(*n)
n1 = n1.Next
} else if n2 != nil && (n1 == nil || getData(n1, 1) < getData(n2, 1)) {
n := LinkedList.NewNode(n2.Data, nil)
l.Insert(*n)
n2 = n2.Next
} else if getData(n1, 1) == getData(n2, 1) {
var tmp [2]int
tmp[0] = getData(n1, 0) + getData(n2, 0)
tmp[1] = getData(n2, 1)
n := LinkedList.NewNode(tmp, nil)
l.Insert(*n)
n1 = n1.Next
n2 = n2.Next
}
}
return l
}
//MultOneTerm use the item from the first multinomial to mul the second multinomial
func MultOneTerm(n *LinkedList.Node, l *LinkedList.LinkedList) *LinkedList.LinkedList {
var newn [2]int
n0 := getData(n, 0)
n1 := getData(n, 1)
newl := LinkedList.NewLinkedList()
ln := l.Head
for ln != nil {
ln0 := getData(ln, 0)
ln1 := getData(ln, 1)
newn[0] = n0 * ln0
newn[1] = n1 + ln1
newl.Insert(*LinkedList.NewNode(newn, nil))
ln = ln.Next
}
return newl
}