這次帶給大家diff演算法使用詳解(附程式碼),diff演算法使用的注意事項有哪些,下面就是實戰案例,一起來看一下。
虛擬dom
diff演算法首先要明確一個概念就是diff的物件是虛擬dom,更新真實dom則是diff演算法的結果
Vnode基底類別
constructor ( 。。。 ) { this.tag = tag this.data = data this.children = children this.text = text this.elm = elm this.ns = undefined this.context = context this.fnContext = undefined this.fnOptions = undefined this.fnScopeId = undefined this.key = data && data.key this.componentOptions = componentOptions this.componentInstance = undefined this.parent = undefined this.raw = false this.isStatic = false this.isRootInsert = true this.isComment = false this.isCloned = false this.isOnce = false this.asyncFactory = asyncFactory this.asyncMeta = undefined this.isAsyncPlaceholder = false }
這個部分的程式碼主要是為了更好地知道在diff演算法中具體diff的屬性的意義,當然也可以更好地了解vnode實例
整體過程
##核心函數是patch函數
function sameVnode (a, b) { return ( a.key === b.key && ( ( a.tag === b.tag && a.isComment === b.isComment && isDef(a.data) === isDef(b.data) && sameInputType(a, b) ) || ( isTrue(a.isAsyncPlaceholder) && a.asyncFactory === b.asyncFactory && isUndef(b.asyncFactory.error) ) ) ) }這裡是一個外層的比較函數,直接去比較了兩個節點的key,tag(標籤),data的比較(注意這裡的data指的是VNodeData),input的話直接比較type。
export interface VNodeData { key?: string | number; slot?: string; scopedSlots?: { [key: string]: ScopedSlot }; ref?: string; tag?: string; staticClass?: string; class?: any; staticStyle?: { [key: string]: any }; style?: object[] | object; props?: { [key: string]: any }; attrs?: { [key: string]: any }; domProps?: { [key: string]: any }; hook?: { [key: string]: Function }; on?: { [key: string]: Function | Function[] }; nativeOn?: { [key: string]: Function | Function[] }; transition?: object; show?: boolean; inlineTemplate?: { render: Function; staticRenderFns: Function[]; }; directives?: VNodeDirective[]; keepAlive?: boolean; }這會確認兩個節點是否有進一步比較的價值,不然直接替換替換的過程主要是一個createElm函數另外則是銷毀oldVNode
// destroy old node if (isDef(parentElm)) { removeVnodes(parentElm, [oldVnode], 0, 0) } else if (isDef(oldVnode.tag)) { invokeDestroyHook(oldVnode) }插入過程簡化來說就是判斷node的type分別呼叫createComponent(會判斷是否有children然後遞迴呼叫)createCommentcreateTextNode#建立後使用insert函數之後需要用hydrate函數將虛擬dom和真是dom進行映射
function insert (parent, elm, ref) { if (isDef(parent)) { if (isDef(ref)) { if (ref.parentNode === parent) { nodeOps.insertBefore(parent, elm, ref) } } else { nodeOps.appendChild(parent, elm) } } }
核心函數
function patchVnode (oldVnode, vnode, insertedVnodeQueue, removeOnly) { if (oldVnode === vnode) { return } const elm = vnode.elm = oldVnode.elm if (isTrue(oldVnode.isAsyncPlaceholder)) { if (isDef(vnode.asyncFactory.resolved)) { hydrate(oldVnode.elm, vnode, insertedVnodeQueue) } else { vnode.isAsyncPlaceholder = true } return } if (isTrue(vnode.isStatic) && isTrue(oldVnode.isStatic) && vnode.key === oldVnode.key && (isTrue(vnode.isCloned) || isTrue(vnode.isOnce)) ) { vnode.componentInstance = oldVnode.componentInstance return } let i const data = vnode.data if (isDef(data) && isDef(i = data.hook) && isDef(i = i.prepatch)) { i(oldVnode, vnode) } const oldCh = oldVnode.children const ch = vnode.children if (isDef(data) && isPatchable(vnode)) { for (i = 0; i < cbs.update.length; ++i) cbs.update[i](oldVnode, vnode) if (isDef(i = data.hook) && isDef(i = i.update)) i(oldVnode, vnode) } if (isUndef(vnode.text)) { if (isDef(oldCh) && isDef(ch)) { if (oldCh !== ch) updateChildren(elm, oldCh, ch, insertedVnodeQueue, removeOnly) } else if (isDef(ch)) { if (isDef(oldVnode.text)) nodeOps.setTextContent(elm, '') addVnodes(elm, null, ch, 0, ch.length - 1, insertedVnodeQueue) } else if (isDef(oldCh)) { removeVnodes(elm, oldCh, 0, oldCh.length - 1) } else if (isDef(oldVnode.text)) { nodeOps.setTextContent(elm, '') } } else if (oldVnode.text !== vnode.text) { nodeOps.setTextContent(elm, vnode.text) } if (isDef(data)) { if (isDef(i = data.hook) && isDef(i = i.postpatch)) i(oldVnode, vnode) } }##const el = vnode.el = oldVnode.el 這是很重要的一步,讓vnode.el引用到現在的真實dom,當el修改時,vnode.el會同步變化。
這部分重點還是關注整個演算法
首先四個指針,oldStart,oldEnd,newStart,newEnd,兩個數組,oldVnode,Vnode 。function updateChildren (parentElm, oldCh, newCh, insertedVnodeQueue, removeOnly) { let oldStartIdx = 0 let newStartIdx = 0 let oldEndIdx = oldCh.length - 1 let oldStartVnode = oldCh[0] let oldEndVnode = oldCh[oldEndIdx] let newEndIdx = newCh.length - 1 let newStartVnode = newCh[0] let newEndVnode = newCh[newEndIdx] let oldKeyToIdx, idxInOld, vnodeToMove, refElm while (oldStartIdx <= oldEndIdx && newStartIdx <= newEndIdx) { if (isUndef(oldStartVnode)) { oldStartVnode = oldCh[++oldStartIdx] // Vnode has been moved left } else if (isUndef(oldEndVnode)) { oldEndVnode = oldCh[--oldEndIdx] } else if (sameVnode(oldStartVnode, newStartVnode)) { patchVnode(oldStartVnode, newStartVnode, insertedVnodeQueue) oldStartVnode = oldCh[++oldStartIdx] newStartVnode = newCh[++newStartIdx] } else if (sameVnode(oldEndVnode, newEndVnode)) { patchVnode(oldEndVnode, newEndVnode, insertedVnodeQueue) oldEndVnode = oldCh[--oldEndIdx] newEndVnode = newCh[--newEndIdx] } else if (sameVnode(oldStartVnode, newEndVnode)) { // Vnode moved right patchVnode(oldStartVnode, newEndVnode, insertedVnodeQueue) canMove && nodeOps.insertBefore(parentElm, oldStartVnode.elm, nodeOps.nextSibling(oldEndVnode.elm)) oldStartVnode = oldCh[++oldStartIdx] newEndVnode = newCh[--newEndIdx] } else if (sameVnode(oldEndVnode, newStartVnode)) { // Vnode moved left patchVnode(oldEndVnode, newStartVnode, insertedVnodeQueue) canMove && nodeOps.insertBefore(parentElm, oldEndVnode.elm, oldStartVnode.elm) oldEndVnode = oldCh[--oldEndIdx] newStartVnode = newCh[++newStartIdx] } else { if (isUndef(oldKeyToIdx)) oldKeyToIdx = createKeyToOldIdx(oldCh, oldStartIdx, oldEndIdx) idxInOld = isDef(newStartVnode.key) ? oldKeyToIdx[newStartVnode.key] : findIdxInOld(newStartVnode, oldCh, oldStartIdx, oldEndIdx) if (isUndef(idxInOld)) { // New element createElm(newStartVnode, insertedVnodeQueue, parentElm, oldStartVnode.elm, false, newCh, newStartIdx) } else { vnodeToMove = oldCh[idxInOld] if (sameVnode(vnodeToMove, newStartVnode)) { patchVnode(vnodeToMove, newStartVnode, insertedVnodeQueue) oldCh[idxInOld] = undefined canMove && nodeOps.insertBefore(parentElm, vnodeToMove.elm, oldStartVnode.elm) } else { // same key but different element. treat as new element createElm(newStartVnode, insertedVnodeQueue, parentElm, oldStartVnode.elm, false, newCh, newStartIdx) } } newStartVnode = newCh[++newStartIdx] } } if (oldStartIdx > oldEndIdx) { refElm = isUndef(newCh[newEndIdx + 1]) ? null : newCh[newEndIdx + 1].elm addVnodes(parentElm, refElm, newCh, newStartIdx, newEndIdx, insertedVnodeQueue) } else if (newStartIdx > newEndIdx) { removeVnodes(parentElm, oldCh, oldStartIdx, oldEndIdx) } }一個循環比較的幾個情況和處理(以下的--均指index的--)比較則是比較的node節點,簡略寫法不嚴謹比較用的是sameVnode函數也不是真的全等整體循環不結束的條件oldStartIdx <= oldEndIdx && newStartIdx <= newEndIdxoldStart === newStart,oldStart newStart
newStart在old中发现一样的那么将这个移动到oldStart前
没有发现一样的那么创建一个放到oldStart之前
循环结束后并没有完成
还有一段判断才算完
if (oldStartIdx > oldEndIdx) { refElm = isUndef(newCh[newEndIdx + 1]) ? null : newCh[newEndIdx + 1].elm addVnodes(parentElm, refElm, newCh, newStartIdx, newEndIdx, insertedVnodeQueue) } else if (newStartIdx > newEndIdx) { removeVnodes(parentElm, oldCh, oldStartIdx, oldEndIdx) }简单的说就是循环结束后,看四个指针中间的内容,old数组中和new数组中,多退少补而已
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