package cache import ( "crypto/sha256" "encoding/hex" "encoding/json" "fmt" "hash/fnv" "log" "net/http" "os" "path/filepath" "proxy-go/internal/config" "proxy-go/internal/utils" "sort" "strings" "sync" "sync/atomic" "time" ) // 内存池用于复用缓冲区 var ( bufferPool = sync.Pool{ New: func() interface{} { return make([]byte, 32*1024) // 32KB 缓冲区 }, } // 大缓冲区池(用于大文件) largeBufPool = sync.Pool{ New: func() interface{} { return make([]byte, 1024*1024) // 1MB 缓冲区 }, } ) // GetBuffer 从池中获取缓冲区 func GetBuffer(size int) []byte { if size <= 32*1024 { buf := bufferPool.Get().([]byte) if cap(buf) >= size { return buf[:size] } bufferPool.Put(buf) } else if size <= 1024*1024 { buf := largeBufPool.Get().([]byte) if cap(buf) >= size { return buf[:size] } largeBufPool.Put(buf) } // 如果池中的缓冲区不够大,创建新的 return make([]byte, size) } // PutBuffer 将缓冲区放回池中 func PutBuffer(buf []byte) { if cap(buf) == 32*1024 { bufferPool.Put(buf) } else if cap(buf) == 1024*1024 { largeBufPool.Put(buf) } // 其他大小的缓冲区让GC处理 } // LRU 缓存节点 type LRUNode struct { key CacheKey value *CacheItem prev *LRUNode next *LRUNode } // LRU 缓存实现 type LRUCache struct { capacity int size int head *LRUNode tail *LRUNode cache map[CacheKey]*LRUNode mu sync.RWMutex } // NewLRUCache 创建LRU缓存 func NewLRUCache(capacity int) *LRUCache { lru := &LRUCache{ capacity: capacity, cache: make(map[CacheKey]*LRUNode), head: &LRUNode{}, tail: &LRUNode{}, } lru.head.next = lru.tail lru.tail.prev = lru.head return lru } // Get 从LRU缓存中获取 func (lru *LRUCache) Get(key CacheKey) (*CacheItem, bool) { lru.mu.Lock() defer lru.mu.Unlock() if node, exists := lru.cache[key]; exists { lru.moveToHead(node) return node.value, true } return nil, false } // Put 向LRU缓存中添加 func (lru *LRUCache) Put(key CacheKey, value *CacheItem) { lru.mu.Lock() defer lru.mu.Unlock() if node, exists := lru.cache[key]; exists { node.value = value lru.moveToHead(node) } else { newNode := &LRUNode{key: key, value: value} lru.cache[key] = newNode lru.addToHead(newNode) lru.size++ if lru.size > lru.capacity { tail := lru.removeTail() delete(lru.cache, tail.key) lru.size-- } } } // Delete 从LRU缓存中删除 func (lru *LRUCache) Delete(key CacheKey) { lru.mu.Lock() defer lru.mu.Unlock() if node, exists := lru.cache[key]; exists { lru.removeNode(node) delete(lru.cache, key) lru.size-- } } // moveToHead 将节点移到头部 func (lru *LRUCache) moveToHead(node *LRUNode) { lru.removeNode(node) lru.addToHead(node) } // addToHead 添加到头部 func (lru *LRUCache) addToHead(node *LRUNode) { node.prev = lru.head node.next = lru.head.next lru.head.next.prev = node lru.head.next = node } // removeNode 移除节点 func (lru *LRUCache) removeNode(node *LRUNode) { node.prev.next = node.next node.next.prev = node.prev } // removeTail 移除尾部节点 func (lru *LRUCache) removeTail() *LRUNode { lastNode := lru.tail.prev lru.removeNode(lastNode) return lastNode } // Range 遍历所有缓存项 func (lru *LRUCache) Range(fn func(key CacheKey, value *CacheItem) bool) { lru.mu.RLock() defer lru.mu.RUnlock() for key, node := range lru.cache { if !fn(key, node.value) { break } } } // Size 返回缓存大小 func (lru *LRUCache) Size() int { lru.mu.RLock() defer lru.mu.RUnlock() return lru.size } // CacheKey 用于标识缓存项的唯一键 type CacheKey struct { URL string AcceptHeaders string UserAgent string } // String 实现 Stringer 接口,用于生成唯一的字符串表示 func (k CacheKey) String() string { return fmt.Sprintf("%s|%s|%s", k.URL, k.AcceptHeaders, k.UserAgent) } // Equal 比较两个 CacheKey 是否相等 func (k CacheKey) Equal(other CacheKey) bool { return k.URL == other.URL && k.AcceptHeaders == other.AcceptHeaders && k.UserAgent == other.UserAgent } // Hash 生成 CacheKey 的哈希值 func (k CacheKey) Hash() uint64 { h := fnv.New64a() h.Write([]byte(k.String())) return h.Sum64() } // CacheItem 表示一个缓存项 type CacheItem struct { FilePath string ContentType string ContentEncoding string Size int64 LastAccess time.Time Hash string CreatedAt time.Time AccessCount int64 Priority int // 缓存优先级 } // CacheStats 缓存统计信息 type CacheStats struct { TotalItems int `json:"total_items"` // 缓存项数量 TotalSize int64 `json:"total_size"` // 总大小 HitCount int64 `json:"hit_count"` // 命中次数 MissCount int64 `json:"miss_count"` // 未命中次数 HitRate float64 `json:"hit_rate"` // 命中率 BytesSaved int64 `json:"bytes_saved"` // 节省的带宽 Enabled bool `json:"enabled"` // 缓存开关状态 } // CacheManager 缓存管理器 type CacheManager struct { cacheDir string items sync.Map // 保持原有的 sync.Map 用于文件缓存 lruCache *LRUCache // 新增LRU缓存用于热点数据 maxAge time.Duration cleanupTick time.Duration maxCacheSize int64 enabled atomic.Bool // 缓存开关 hitCount atomic.Int64 // 命中计数 missCount atomic.Int64 // 未命中计数 bytesSaved atomic.Int64 // 节省的带宽 cleanupTimer *time.Ticker // 添加清理定时器 stopCleanup chan struct{} // 添加停止信号通道 // ExtensionMatcher缓存 extensionMatcherCache *ExtensionMatcherCache // 缓存预热 prewarming atomic.Bool } // NewCacheManager 创建新的缓存管理器 func NewCacheManager(cacheDir string) (*CacheManager, error) { if err := os.MkdirAll(cacheDir, 0755); err != nil { return nil, fmt.Errorf("failed to create cache directory: %v", err) } cm := &CacheManager{ cacheDir: cacheDir, lruCache: NewLRUCache(10000), // 10000个热点缓存项 maxAge: 30 * time.Minute, cleanupTick: 5 * time.Minute, maxCacheSize: 10 * 1024 * 1024 * 1024, // 10GB stopCleanup: make(chan struct{}), // 初始化ExtensionMatcher缓存 extensionMatcherCache: NewExtensionMatcherCache(), } cm.enabled.Store(true) // 默认启用缓存 // 尝试加载配置 if err := cm.loadConfig(); err != nil { log.Printf("[Cache] Failed to load config: %v, using default values", err) } // 启动时清理过期和临时文件 if err := cm.cleanStaleFiles(); err != nil { log.Printf("[Cache] Failed to clean stale files: %v", err) } // 启动清理协程 cm.startCleanup() // 启动缓存预热 go cm.prewarmCache() return cm, nil } // GenerateCacheKey 生成缓存键 func (cm *CacheManager) GenerateCacheKey(r *http.Request) CacheKey { // 处理 Vary 头部 varyHeaders := make([]string, 0) for _, vary := range strings.Split(r.Header.Get("Vary"), ",") { vary = strings.TrimSpace(vary) if vary != "" { value := r.Header.Get(vary) varyHeaders = append(varyHeaders, vary+"="+value) } } sort.Strings(varyHeaders) return CacheKey{ URL: r.URL.String(), AcceptHeaders: r.Header.Get("Accept"), UserAgent: r.Header.Get("User-Agent"), } } // Get 获取缓存项 func (cm *CacheManager) Get(key CacheKey, r *http.Request) (*CacheItem, bool, bool) { if !cm.enabled.Load() { return nil, false, false } // 检查LRU缓存 if item, found := cm.lruCache.Get(key); found { // 检查LRU缓存项是否过期 if time.Since(item.LastAccess) > cm.maxAge { cm.lruCache.Delete(key) cm.missCount.Add(1) return nil, false, false } // 更新访问时间 item.LastAccess = time.Now() atomic.AddInt64(&item.AccessCount, 1) cm.hitCount.Add(1) return item, true, false } // 检查文件缓存 value, ok := cm.items.Load(key) if !ok { cm.missCount.Add(1) return nil, false, false } item := value.(*CacheItem) // 验证文件是否存在 if _, err := os.Stat(item.FilePath); err != nil { cm.items.Delete(key) cm.missCount.Add(1) return nil, false, false } // 检查是否过期(使用LastAccess而不是CreatedAt) if time.Since(item.LastAccess) > cm.maxAge { cm.items.Delete(key) os.Remove(item.FilePath) cm.missCount.Add(1) return nil, false, false } // 更新访问信息(重置过期时间) item.LastAccess = time.Now() atomic.AddInt64(&item.AccessCount, 1) cm.hitCount.Add(1) cm.bytesSaved.Add(item.Size) // 将缓存项添加到LRU缓存 cm.lruCache.Put(key, item) return item, true, false } // Put 添加缓存项 func (cm *CacheManager) Put(key CacheKey, resp *http.Response, body []byte) (*CacheItem, error) { // 只检查基本的响应状态 if resp.StatusCode != http.StatusOK { return nil, fmt.Errorf("response status not OK") } // 计算内容哈希 contentHash := sha256.Sum256(body) hashStr := hex.EncodeToString(contentHash[:]) // 检查是否存在相同哈希的缓存项 var existingItem *CacheItem cm.items.Range(func(k, v interface{}) bool { if item := v.(*CacheItem); item.Hash == hashStr { if _, err := os.Stat(item.FilePath); err == nil { existingItem = item return false } cm.items.Delete(k) } return true }) if existingItem != nil { cm.items.Store(key, existingItem) log.Printf("[Cache] HIT %s %s (%s) from %s", resp.Request.Method, key.URL, formatBytes(existingItem.Size), utils.GetRequestSource(resp.Request)) return existingItem, nil } // 生成文件名并存储 fileName := hashStr filePath := filepath.Join(cm.cacheDir, fileName) if err := os.WriteFile(filePath, body, 0600); err != nil { return nil, fmt.Errorf("failed to write cache file: %v", err) } item := &CacheItem{ FilePath: filePath, ContentType: resp.Header.Get("Content-Type"), ContentEncoding: resp.Header.Get("Content-Encoding"), Size: int64(len(body)), LastAccess: time.Now(), Hash: hashStr, CreatedAt: time.Now(), AccessCount: 1, } cm.items.Store(key, item) method := "GET" if resp.Request != nil { method = resp.Request.Method } log.Printf("[Cache] NEW %s %s (%s) from %s", method, key.URL, formatBytes(item.Size), utils.GetRequestSource(resp.Request)) return item, nil } // cleanup 定期清理过期的缓存项 func (cm *CacheManager) cleanup() { var totalSize int64 var keysToDelete []CacheKey // 收集需要删除的键和计算总大小 cm.items.Range(func(k, v interface{}) bool { key := k.(CacheKey) item := v.(*CacheItem) totalSize += item.Size if time.Since(item.LastAccess) > cm.maxAge { keysToDelete = append(keysToDelete, key) } return true }) // 如果总大小超过限制,按最后访问时间排序删除 if totalSize > cm.maxCacheSize { var items []*CacheItem cm.items.Range(func(k, v interface{}) bool { items = append(items, v.(*CacheItem)) return true }) // 按最后访问时间排序 sort.Slice(items, func(i, j int) bool { return items[i].LastAccess.Before(items[j].LastAccess) }) // 删除最旧的项直到总大小小于限制 for _, item := range items { if totalSize <= cm.maxCacheSize { break } cm.items.Range(func(k, v interface{}) bool { if v.(*CacheItem) == item { keysToDelete = append(keysToDelete, k.(CacheKey)) totalSize -= item.Size return false } return true }) } } // 删除过期和超出大小限制的缓存项 for _, key := range keysToDelete { if item, ok := cm.items.Load(key); ok { cacheItem := item.(*CacheItem) os.Remove(cacheItem.FilePath) cm.items.Delete(key) log.Printf("[Cache] DEL %s (expired)", key.URL) } } } // formatBytes 格式化字节大小 func formatBytes(bytes int64) string { const ( KB = 1024 MB = 1024 * KB GB = 1024 * MB ) switch { case bytes >= GB: return fmt.Sprintf("%.2f GB", float64(bytes)/float64(GB)) case bytes >= MB: return fmt.Sprintf("%.2f MB", float64(bytes)/float64(MB)) case bytes >= KB: return fmt.Sprintf("%.2f KB", float64(bytes)/float64(KB)) default: return fmt.Sprintf("%d B", bytes) } } // GetStats 获取缓存统计信息 func (cm *CacheManager) GetStats() CacheStats { var totalItems int var totalSize int64 cm.items.Range(func(_, value interface{}) bool { item := value.(*CacheItem) totalItems++ totalSize += item.Size return true }) hitCount := cm.hitCount.Load() missCount := cm.missCount.Load() totalRequests := hitCount + missCount hitRate := float64(0) if totalRequests > 0 { hitRate = float64(hitCount) / float64(totalRequests) * 100 } return CacheStats{ TotalItems: totalItems, TotalSize: totalSize, HitCount: hitCount, MissCount: missCount, HitRate: hitRate, BytesSaved: cm.bytesSaved.Load(), Enabled: cm.enabled.Load(), } } // SetEnabled 设置缓存开关状态 func (cm *CacheManager) SetEnabled(enabled bool) { cm.enabled.Store(enabled) } // ClearCache 清空缓存 func (cm *CacheManager) ClearCache() error { // 清除内存中的缓存项 var keysToDelete []CacheKey cm.items.Range(func(key, value interface{}) bool { cacheKey := key.(CacheKey) keysToDelete = append(keysToDelete, cacheKey) return true }) for _, key := range keysToDelete { cm.items.Delete(key) } // 清理缓存目录中的所有文件 entries, err := os.ReadDir(cm.cacheDir) if err != nil { return fmt.Errorf("failed to read cache directory: %v", err) } for _, entry := range entries { if entry.Name() == "config.json" { continue // 保留配置文件 } filePath := filepath.Join(cm.cacheDir, entry.Name()) if err := os.Remove(filePath); err != nil { log.Printf("[Cache] ERR Failed to remove file: %s", entry.Name()) } } // 重置统计信息 cm.hitCount.Store(0) cm.missCount.Store(0) cm.bytesSaved.Store(0) return nil } // cleanStaleFiles 清理过期和临时文件 func (cm *CacheManager) cleanStaleFiles() error { entries, err := os.ReadDir(cm.cacheDir) if err != nil { return fmt.Errorf("failed to read cache directory: %v", err) } for _, entry := range entries { if entry.Name() == "config.json" { continue // 保留配置文件 } filePath := filepath.Join(cm.cacheDir, entry.Name()) // 清理临时文件 if strings.HasPrefix(entry.Name(), "temp-") { if err := os.Remove(filePath); err != nil { log.Printf("[Cache] ERR Failed to remove temp file: %s", entry.Name()) } continue } // 检查文件是否仍在缓存记录中 fileFound := false cm.items.Range(func(_, value interface{}) bool { item := value.(*CacheItem) if item.FilePath == filePath { fileFound = true return false } return true }) // 如果文件不在缓存记录中,删除它 if !fileFound { if err := os.Remove(filePath); err != nil { log.Printf("[Cache] ERR Failed to remove stale file: %s", entry.Name()) } } } return nil } // CreateTemp 创建临时缓存文件 func (cm *CacheManager) CreateTemp(key CacheKey, resp *http.Response) (*os.File, error) { if !cm.enabled.Load() { return nil, fmt.Errorf("cache is disabled") } // 创建临时文件 tempFile, err := os.CreateTemp(cm.cacheDir, "temp-*") if err != nil { return nil, fmt.Errorf("failed to create temp file: %v", err) } return tempFile, nil } // Commit 提交缓存文件 func (cm *CacheManager) Commit(key CacheKey, tempPath string, resp *http.Response, size int64) error { if !cm.enabled.Load() { os.Remove(tempPath) return fmt.Errorf("cache is disabled") } // 生成最终的缓存文件名 h := sha256.New() h.Write([]byte(key.String())) hashStr := hex.EncodeToString(h.Sum(nil)) ext := filepath.Ext(key.URL) if ext == "" { ext = ".bin" } filePath := filepath.Join(cm.cacheDir, hashStr+ext) // 重命名临时文件 if err := os.Rename(tempPath, filePath); err != nil { os.Remove(tempPath) return fmt.Errorf("failed to rename temp file: %v", err) } // 创建缓存项 item := &CacheItem{ FilePath: filePath, ContentType: resp.Header.Get("Content-Type"), ContentEncoding: resp.Header.Get("Content-Encoding"), Size: size, LastAccess: time.Now(), Hash: hashStr, CreatedAt: time.Now(), AccessCount: 1, } cm.items.Store(key, item) cm.bytesSaved.Add(size) log.Printf("[Cache] NEW %s %s (%s)", resp.Request.Method, key.URL, formatBytes(size)) return nil } // GetConfig 获取缓存配置 func (cm *CacheManager) GetConfig() CacheConfig { return CacheConfig{ MaxAge: int64(cm.maxAge.Minutes()), CleanupTick: int64(cm.cleanupTick.Minutes()), MaxCacheSize: cm.maxCacheSize / (1024 * 1024 * 1024), // 转换为GB } } // UpdateConfig 更新缓存配置 func (cm *CacheManager) UpdateConfig(maxAge, cleanupTick, maxCacheSize int64) error { if maxAge <= 0 || cleanupTick <= 0 || maxCacheSize <= 0 { return fmt.Errorf("invalid config values: all values must be positive") } cm.maxAge = time.Duration(maxAge) * time.Minute cm.maxCacheSize = maxCacheSize * 1024 * 1024 * 1024 // 转换为字节 // 如果清理间隔发生变化,重启清理协程 newCleanupTick := time.Duration(cleanupTick) * time.Minute if cm.cleanupTick != newCleanupTick { cm.cleanupTick = newCleanupTick // 停止当前的清理协程 cm.stopCleanup <- struct{}{} // 启动新的清理协程 cm.startCleanup() } // 保存配置到文件 if err := cm.saveConfig(); err != nil { log.Printf("[Cache] Failed to save config: %v", err) } return nil } // CacheConfig 缓存配置结构 type CacheConfig struct { MaxAge int64 `json:"max_age"` // 最大缓存时间(分钟) CleanupTick int64 `json:"cleanup_tick"` // 清理间隔(分钟) MaxCacheSize int64 `json:"max_cache_size"` // 最大缓存大小(GB) } // startCleanup 启动清理协程 func (cm *CacheManager) startCleanup() { cm.cleanupTimer = time.NewTicker(cm.cleanupTick) go func() { for { select { case <-cm.cleanupTimer.C: cm.cleanup() case <-cm.stopCleanup: cm.cleanupTimer.Stop() return } } }() } // saveConfig 保存配置到文件 func (cm *CacheManager) saveConfig() error { config := CacheConfig{ MaxAge: int64(cm.maxAge.Minutes()), CleanupTick: int64(cm.cleanupTick.Minutes()), MaxCacheSize: cm.maxCacheSize / (1024 * 1024 * 1024), // 转换为GB } configPath := filepath.Join(cm.cacheDir, "config.json") data, err := json.Marshal(config) if err != nil { return fmt.Errorf("failed to marshal config: %v", err) } if err := os.WriteFile(configPath, data, 0600); err != nil { return fmt.Errorf("failed to write config file: %v", err) } return nil } // loadConfig 从文件加载配置 func (cm *CacheManager) loadConfig() error { configPath := filepath.Join(cm.cacheDir, "config.json") data, err := os.ReadFile(configPath) if err != nil { if os.IsNotExist(err) { // 如果配置文件不存在,使用默认配置并保存 return cm.saveConfig() } return fmt.Errorf("failed to read config file: %v", err) } var config CacheConfig if err := json.Unmarshal(data, &config); err != nil { return fmt.Errorf("failed to unmarshal config: %v", err) } // 更新配置 cm.maxAge = time.Duration(config.MaxAge) * time.Minute cm.maxCacheSize = config.MaxCacheSize * 1024 * 1024 * 1024 // 转换为字节 // 如果清理间隔发生变化,重启清理协程 newCleanupTick := time.Duration(config.CleanupTick) * time.Minute if cm.cleanupTick != newCleanupTick { cm.cleanupTick = newCleanupTick if cm.cleanupTimer != nil { cm.stopCleanup <- struct{}{} } cm.startCleanup() } return nil } // GetExtensionMatcher 获取缓存的ExtensionMatcher func (cm *CacheManager) GetExtensionMatcher(pathKey string, rules []config.ExtensionRule) *utils.ExtensionMatcher { if cm.extensionMatcherCache == nil { return utils.NewExtensionMatcher(rules) } return cm.extensionMatcherCache.GetOrCreate(pathKey, rules) } // InvalidateExtensionMatcherPath 使指定路径的ExtensionMatcher缓存失效 func (cm *CacheManager) InvalidateExtensionMatcherPath(pathKey string) { if cm.extensionMatcherCache != nil { cm.extensionMatcherCache.InvalidatePath(pathKey) } } // InvalidateAllExtensionMatchers 清空所有ExtensionMatcher缓存 func (cm *CacheManager) InvalidateAllExtensionMatchers() { if cm.extensionMatcherCache != nil { cm.extensionMatcherCache.InvalidateAll() } } // GetExtensionMatcherStats 获取ExtensionMatcher缓存统计信息 func (cm *CacheManager) GetExtensionMatcherStats() ExtensionMatcherCacheStats { if cm.extensionMatcherCache != nil { return cm.extensionMatcherCache.GetStats() } return ExtensionMatcherCacheStats{} } // UpdateExtensionMatcherConfig 更新ExtensionMatcher缓存配置 func (cm *CacheManager) UpdateExtensionMatcherConfig(maxAge, cleanupTick time.Duration) { if cm.extensionMatcherCache != nil { cm.extensionMatcherCache.UpdateConfig(maxAge, cleanupTick) } } // Stop 停止缓存管理器(包括ExtensionMatcher缓存) func (cm *CacheManager) Stop() { // 停止主缓存清理 if cm.cleanupTimer != nil { cm.cleanupTimer.Stop() } close(cm.stopCleanup) // 停止ExtensionMatcher缓存 if cm.extensionMatcherCache != nil { cm.extensionMatcherCache.Stop() } } // prewarmCache 启动缓存预热 func (cm *CacheManager) prewarmCache() { // 模拟一些请求来预热缓存 // 实际应用中,这里会从数据库或外部服务加载热点数据 // 例如,从数据库加载最近访问频率高的URL // 或者从外部API获取热门资源 // 示例:加载最近访问的URL // 假设我们有一个数据库或文件,记录最近访问的URL和它们的哈希 // 这里我们简单地加载一些示例URL exampleUrls := []string{ "https://example.com/api/data", "https://api.github.com/repos/golang/go/releases", "https://api.openai.com/v1/models", "https://api.openai.com/v1/chat/completions", } for _, url := range exampleUrls { // 生成一个随机的Accept Headers和UserAgent acceptHeaders := "application/json" userAgent := "Mozilla/5.0 (compatible; ProxyGo/1.0)" // 模拟一个HTTP请求 req, err := http.NewRequest("GET", url, nil) if err != nil { log.Printf("[Cache] ERR Failed to create request for prewarming: %v", err) continue } req.Header.Set("Accept", acceptHeaders) req.Header.Set("User-Agent", userAgent) // 生成缓存键 cacheKey := cm.GenerateCacheKey(req) // 尝试从LRU缓存获取 if _, found := cm.lruCache.Get(cacheKey); found { log.Printf("[Cache] WARN %s (prewarmed)", cacheKey.URL) continue } // 尝试从文件缓存获取 if _, ok := cm.items.Load(cacheKey); ok { log.Printf("[Cache] WARN %s (prewarmed)", cacheKey.URL) continue } // 模拟一个HTTP响应 resp := &http.Response{ StatusCode: http.StatusOK, Header: make(http.Header), Request: req, } resp.Header.Set("Content-Type", "application/json") resp.Header.Set("Content-Encoding", "gzip") resp.Header.Set("X-Cache", "HIT") // 模拟缓存命中 // 模拟一个HTTP请求体 body := []byte(`{"message": "Hello from prewarmed cache"}`) // 添加到LRU缓存 contentHash := sha256.Sum256(body) cm.lruCache.Put(cacheKey, &CacheItem{ FilePath: "", // 文件缓存,这里不需要 ContentType: "application/json", ContentEncoding: "gzip", Size: int64(len(body)), LastAccess: time.Now(), Hash: hex.EncodeToString(contentHash[:]), CreatedAt: time.Now(), AccessCount: 1, }) log.Printf("[Cache] PREWARM %s", cacheKey.URL) } }