package gzhttp import ( "bufio" "crypto/rand" "crypto/sha256" "encoding/binary" "errors" "fmt" "hash/crc32" "io" "math" "math/bits" "mime" "net" "net/http" "strconv" "strings" "sync" "github.com/klauspost/compress/gzhttp/writer" "github.com/klauspost/compress/gzhttp/writer/gzkp" "github.com/klauspost/compress/gzip" ) const ( // HeaderNoCompression can be used to disable compression. // Any header value will disable compression. // The Header is always removed from output. HeaderNoCompression = "No-Gzip-Compression" vary = "Vary" acceptEncoding = "Accept-Encoding" contentEncoding = "Content-Encoding" contentRange = "Content-Range" acceptRanges = "Accept-Ranges" contentType = "Content-Type" contentLength = "Content-Length" eTag = "ETag" ) type codings map[string]float64 const ( // DefaultQValue is the default qvalue to assign to an encoding if no explicit qvalue is set. // This is actually kind of ambiguous in RFC 2616, so hopefully it's correct. // The examples seem to indicate that it is. DefaultQValue = 1.0 // DefaultMinSize is the default minimum size until we enable gzip compression. // 1500 bytes is the MTU size for the internet since that is the largest size allowed at the network layer. // If you take a file that is 1300 bytes and compress it to 800 bytes, it’s still transmitted in that same 1500 byte packet regardless, so you’ve gained nothing. // That being the case, you should restrict the gzip compression to files with a size (plus header) greater than a single packet, // 1024 bytes (1KB) is therefore default. DefaultMinSize = 1024 ) // GzipResponseWriter provides an http.ResponseWriter interface, which gzips // bytes before writing them to the underlying response. This doesn't close the // writers, so don't forget to do that. // It can be configured to skip response smaller than minSize. type GzipResponseWriter struct { http.ResponseWriter level int gwFactory writer.GzipWriterFactory gw writer.GzipWriter code int // Saves the WriteHeader value. minSize int // Specifies the minimum response size to gzip. If the response length is bigger than this value, it is compressed. buf []byte // Holds the first part of the write before reaching the minSize or the end of the write. ignore bool // If true, then we immediately passthru writes to the underlying ResponseWriter. keepAcceptRanges bool // Keep "Accept-Ranges" header. setContentType bool // Add content type, if missing and detected. suffixETag string // Suffix to add to ETag header if response is compressed. dropETag bool // Drop ETag header if response is compressed (supersedes suffixETag). sha256Jitter bool // Use sha256 for jitter. randomJitter string // Add random bytes to output as header field. jitterBuffer int // Maximum buffer to accumulate before doing jitter. contentTypeFilter func(ct string) bool // Only compress if the response is one of these content-types. All are accepted if empty. } type GzipResponseWriterWithCloseNotify struct { *GzipResponseWriter } func (w GzipResponseWriterWithCloseNotify) CloseNotify() <-chan bool { return w.ResponseWriter.(http.CloseNotifier).CloseNotify() } // Write appends data to the gzip writer. func (w *GzipResponseWriter) Write(b []byte) (int, error) { // GZIP responseWriter is initialized. Use the GZIP responseWriter. if w.gw != nil { return w.gw.Write(b) } // If we have already decided not to use GZIP, immediately passthrough. if w.ignore { return w.ResponseWriter.Write(b) } // Save the write into a buffer for later use in GZIP responseWriter // (if content is long enough) or at close with regular responseWriter. wantBuf := 512 if w.minSize > wantBuf { wantBuf = w.minSize } if w.jitterBuffer > 0 && w.jitterBuffer > wantBuf { wantBuf = w.jitterBuffer } toAdd := len(b) if len(w.buf)+toAdd > wantBuf { toAdd = wantBuf - len(w.buf) } w.buf = append(w.buf, b[:toAdd]...) remain := b[toAdd:] hdr := w.Header() // Only continue if they didn't already choose an encoding or a known unhandled content length or type. if len(hdr[HeaderNoCompression]) == 0 && hdr.Get(contentEncoding) == "" && hdr.Get(contentRange) == "" { // Check more expensive parts now. cl, _ := atoi(hdr.Get(contentLength)) ct := hdr.Get(contentType) if cl == 0 || cl >= w.minSize && (ct == "" || w.contentTypeFilter(ct)) { // If the current buffer is less than minSize and a Content-Length isn't set, then wait until we have more data. if len(w.buf) < w.minSize && cl == 0 || (w.jitterBuffer > 0 && len(w.buf) < w.jitterBuffer) { return len(b), nil } // If the Content-Length is larger than minSize or the current buffer is larger than minSize, then continue. if cl >= w.minSize || len(w.buf) >= w.minSize { // If a Content-Type wasn't specified, infer it from the current buffer. if ct == "" { ct = http.DetectContentType(w.buf) } // Handles the intended case of setting a nil Content-Type (as for http/server or http/fs) // Set the header only if the key does not exist if _, ok := hdr[contentType]; w.setContentType && !ok { hdr.Set(contentType, ct) } // If the Content-Type is acceptable to GZIP, initialize the GZIP writer. if w.contentTypeFilter(ct) { if err := w.startGzip(remain); err != nil { return 0, err } if len(remain) > 0 { if _, err := w.gw.Write(remain); err != nil { return 0, err } } return len(b), nil } } } } // If we got here, we should not GZIP this response. if err := w.startPlain(); err != nil { return 0, err } if len(remain) > 0 { if _, err := w.ResponseWriter.Write(remain); err != nil { return 0, err } } return len(b), nil } func (w *GzipResponseWriter) Unwrap() http.ResponseWriter { return w.ResponseWriter } var castagnoliTable = crc32.MakeTable(crc32.Castagnoli) // startGzip initializes a GZIP writer and writes the buffer. func (w *GzipResponseWriter) startGzip(remain []byte) error { // Set the GZIP header. w.Header().Set(contentEncoding, "gzip") // if the Content-Length is already set, then calls to Write on gzip // will fail to set the Content-Length header since its already set // See: https://github.com/golang/go/issues/14975. w.Header().Del(contentLength) // Delete Accept-Ranges. if !w.keepAcceptRanges { w.Header().Del(acceptRanges) } // Suffix ETag. if w.suffixETag != "" && !w.dropETag && w.Header().Get(eTag) != "" { orig := w.Header().Get(eTag) insertPoint := strings.LastIndex(orig, `"`) if insertPoint == -1 { insertPoint = len(orig) } w.Header().Set(eTag, orig[:insertPoint]+w.suffixETag+orig[insertPoint:]) } // Delete ETag. if w.dropETag { w.Header().Del(eTag) } // Write the header to gzip response. if w.code != 0 { w.ResponseWriter.WriteHeader(w.code) // Ensure that no other WriteHeader's happen w.code = 0 } // Initialize and flush the buffer into the gzip response if there are any bytes. // If there aren't any, we shouldn't initialize it yet because on Close it will // write the gzip header even if nothing was ever written. if len(w.buf) > 0 { // Initialize the GZIP response. w.init() // Set random jitter based on CRC or SHA-256 of current buffer. // Before first write. if len(w.randomJitter) > 0 { var jitRNG uint32 if w.jitterBuffer > 0 { if w.sha256Jitter { h := sha256.New() h.Write(w.buf) // Use only up to "w.jitterBuffer", otherwise the output depends on write sizes. if len(remain) > 0 && len(w.buf) < w.jitterBuffer { remain := remain if len(remain)+len(w.buf) > w.jitterBuffer { remain = remain[:w.jitterBuffer-len(w.buf)] } h.Write(remain) } var tmp [sha256.Size]byte jitRNG = binary.LittleEndian.Uint32(h.Sum(tmp[:0])) } else { h := crc32.Update(0, castagnoliTable, w.buf) // Use only up to "w.jitterBuffer", otherwise the output depends on write sizes. if len(remain) > 0 && len(w.buf) < w.jitterBuffer { remain := remain if len(remain)+len(w.buf) > w.jitterBuffer { remain = remain[:w.jitterBuffer-len(w.buf)] } h = crc32.Update(h, castagnoliTable, remain) } jitRNG = bits.RotateLeft32(h, 19) ^ 0xab0755de } } else { // Get from rand.Reader var tmp [4]byte _, err := rand.Read(tmp[:]) if err != nil { return fmt.Errorf("gzhttp: %w", err) } jitRNG = binary.LittleEndian.Uint32(tmp[:]) } jit := w.randomJitter[:1+jitRNG%uint32(len(w.randomJitter)-1)] w.gw.(writer.GzipWriterExt).SetHeader(writer.Header{Comment: jit}) } n, err := w.gw.Write(w.buf) // This should never happen (per io.Writer docs), but if the write didn't // accept the entire buffer but returned no specific error, we have no clue // what's going on, so abort just to be safe. if err == nil && n < len(w.buf) { err = io.ErrShortWrite } w.buf = w.buf[:0] return err } return nil } // startPlain writes to sent bytes and buffer the underlying ResponseWriter without gzip. func (w *GzipResponseWriter) startPlain() error { w.Header().Del(HeaderNoCompression) if w.code != 0 { w.ResponseWriter.WriteHeader(w.code) // Ensure that no other WriteHeader's happen w.code = 0 } w.ignore = true // If Write was never called then don't call Write on the underlying ResponseWriter. if len(w.buf) == 0 { return nil } n, err := w.ResponseWriter.Write(w.buf) // This should never happen (per io.Writer docs), but if the write didn't // accept the entire buffer but returned no specific error, we have no clue // what's going on, so abort just to be safe. if err == nil && n < len(w.buf) { err = io.ErrShortWrite } w.buf = w.buf[:0] return err } // WriteHeader just saves the response code until close or GZIP effective writes. // In the specific case of 1xx status codes, WriteHeader is directly calling the wrapped ResponseWriter. func (w *GzipResponseWriter) WriteHeader(code int) { // Handle informational headers // This is gated to not forward 1xx responses on builds prior to go1.20. if shouldWrite1xxResponses() && code >= 100 && code <= 199 { w.ResponseWriter.WriteHeader(code) return } if w.code == 0 { w.code = code } } // init graps a new gzip writer from the gzipWriterPool and writes the correct // content encoding header. func (w *GzipResponseWriter) init() { // Bytes written during ServeHTTP are redirected to this gzip writer // before being written to the underlying response. w.gw = w.gwFactory.New(w.ResponseWriter, w.level) } // Close will close the gzip.Writer and will put it back in the gzipWriterPool. func (w *GzipResponseWriter) Close() error { if w.ignore { return nil } if w.gw == nil { var ( ct = w.Header().Get(contentType) ce = w.Header().Get(contentEncoding) cr = w.Header().Get(contentRange) ) // fmt.Println(len(w.buf) == 0, len(w.buf) < w.minSize, len(w.Header()[HeaderNoCompression]) != 0, ce != "", cr != "", !w.contentTypeFilter(ct)) if len(w.buf) == 0 || len(w.buf) < w.minSize || len(w.Header()[HeaderNoCompression]) != 0 || ce != "" || cr != "" || !w.contentTypeFilter(ct) { // GZIP not triggered, write out regular response. return w.startPlain() } err := w.startGzip(nil) if err != nil { return err } } err := w.gw.Close() w.gw = nil return err } // Flush flushes the underlying *gzip.Writer and then the underlying // http.ResponseWriter if it is an http.Flusher. This makes GzipResponseWriter // an http.Flusher. // If not enough bytes has been written to determine if we have reached minimum size, // this will be ignored. // If nothing has been written yet, nothing will be flushed. func (w *GzipResponseWriter) Flush() { if w.gw == nil && !w.ignore { if len(w.buf) == 0 { // Nothing written yet. return } var ( cl, _ = atoi(w.Header().Get(contentLength)) ct = w.Header().Get(contentType) ce = w.Header().Get(contentEncoding) cr = w.Header().Get(contentRange) ) if ct == "" { ct = http.DetectContentType(w.buf) // Handles the intended case of setting a nil Content-Type (as for http/server or http/fs) // Set the header only if the key does not exist if _, ok := w.Header()[contentType]; w.setContentType && !ok { w.Header().Set(contentType, ct) } } if cl == 0 { // Assume minSize. cl = w.minSize } // See if we should compress... if len(w.Header()[HeaderNoCompression]) == 0 && ce == "" && cr == "" && cl >= w.minSize && w.contentTypeFilter(ct) { w.startGzip(nil) } else { w.startPlain() } } if w.gw != nil { w.gw.Flush() } if fw, ok := w.ResponseWriter.(http.Flusher); ok { fw.Flush() } } // Hijack implements http.Hijacker. If the underlying ResponseWriter is a // Hijacker, its Hijack method is returned. Otherwise an error is returned. func (w *GzipResponseWriter) Hijack() (net.Conn, *bufio.ReadWriter, error) { if hj, ok := w.ResponseWriter.(http.Hijacker); ok { return hj.Hijack() } return nil, nil, fmt.Errorf("http.Hijacker interface is not supported") } // verify Hijacker interface implementation var _ http.Hijacker = &GzipResponseWriter{} var onceDefault sync.Once var defaultWrapper func(http.Handler) http.HandlerFunc // GzipHandler allows to easily wrap an http handler with default settings. func GzipHandler(h http.Handler) http.HandlerFunc { onceDefault.Do(func() { var err error defaultWrapper, err = NewWrapper() if err != nil { panic(err) } }) return defaultWrapper(h) } var grwPool = sync.Pool{New: func() interface{} { return &GzipResponseWriter{} }} // NewWrapper returns a reusable wrapper with the supplied options. func NewWrapper(opts ...option) (func(http.Handler) http.HandlerFunc, error) { c := &config{ level: gzip.DefaultCompression, minSize: DefaultMinSize, writer: writer.GzipWriterFactory{ Levels: gzkp.Levels, New: gzkp.NewWriter, }, contentTypes: DefaultContentTypeFilter, setContentType: true, } for _, o := range opts { o(c) } if err := c.validate(); err != nil { return nil, err } return func(h http.Handler) http.HandlerFunc { return func(w http.ResponseWriter, r *http.Request) { w.Header().Add(vary, acceptEncoding) if acceptsGzip(r) { gw := grwPool.Get().(*GzipResponseWriter) *gw = GzipResponseWriter{ ResponseWriter: w, gwFactory: c.writer, level: c.level, minSize: c.minSize, contentTypeFilter: c.contentTypes, keepAcceptRanges: c.keepAcceptRanges, dropETag: c.dropETag, suffixETag: c.suffixETag, buf: gw.buf, setContentType: c.setContentType, randomJitter: c.randomJitter, jitterBuffer: c.jitterBuffer, sha256Jitter: c.sha256Jitter, } if len(gw.buf) > 0 { gw.buf = gw.buf[:0] } defer func() { gw.Close() gw.ResponseWriter = nil grwPool.Put(gw) }() if _, ok := w.(http.CloseNotifier); ok { gwcn := GzipResponseWriterWithCloseNotify{gw} h.ServeHTTP(gwcn, r) } else { h.ServeHTTP(gw, r) } w.Header().Del(HeaderNoCompression) } else { h.ServeHTTP(newNoGzipResponseWriter(w), r) w.Header().Del(HeaderNoCompression) } } }, nil } // Parsed representation of one of the inputs to ContentTypes. // See https://golang.org/pkg/mime/#ParseMediaType type parsedContentType struct { mediaType string params map[string]string } // equals returns whether this content type matches another content type. func (pct parsedContentType) equals(mediaType string, params map[string]string) bool { if pct.mediaType != mediaType { return false } // if pct has no params, don't care about other's params if len(pct.params) == 0 { return true } // if pct has any params, they must be identical to other's. if len(pct.params) != len(params) { return false } for k, v := range pct.params { if w, ok := params[k]; !ok || v != w { return false } } return true } // Used for functional configuration. type config struct { minSize int level int writer writer.GzipWriterFactory contentTypes func(ct string) bool keepAcceptRanges bool setContentType bool suffixETag string dropETag bool jitterBuffer int randomJitter string sha256Jitter bool } func (c *config) validate() error { min, max := c.writer.Levels() if c.level < min || c.level > max { return fmt.Errorf("invalid compression level requested: %d, valid range %d -> %d", c.level, min, max) } if c.minSize < 0 { return fmt.Errorf("minimum size must be more than zero") } if len(c.randomJitter) >= math.MaxUint16 { return fmt.Errorf("random jitter size exceeded") } if len(c.randomJitter) > 0 { gzw, ok := c.writer.New(io.Discard, c.level).(writer.GzipWriterExt) if !ok { return errors.New("the custom compressor does not allow setting headers for random jitter") } gzw.Close() } return nil } type option func(c *config) func MinSize(size int) option { return func(c *config) { c.minSize = size } } // CompressionLevel sets the compression level func CompressionLevel(level int) option { return func(c *config) { c.level = level } } // SetContentType sets the content type before returning // requests, if unset before returning, and it was detected. // Default: true. func SetContentType(b bool) option { return func(c *config) { c.setContentType = b } } // Implementation changes the implementation of GzipWriter // // The default implementation is backed by github.com/klauspost/compress // To support RandomJitter, the GzipWriterExt must also be // supported by the returned writers. func Implementation(writer writer.GzipWriterFactory) option { return func(c *config) { c.writer = writer } } // ContentTypes specifies a list of content types to compare // the Content-Type header to before compressing. If none // match, the response will be returned as-is. // // Content types are compared in a case-insensitive, whitespace-ignored // manner. // // A MIME type without any other directive will match a content type // that has the same MIME type, regardless of that content type's other // directives. I.e., "text/html" will match both "text/html" and // "text/html; charset=utf-8". // // A MIME type with any other directive will only match a content type // that has the same MIME type and other directives. I.e., // "text/html; charset=utf-8" will only match "text/html; charset=utf-8". // // By default common compressed audio, video and archive formats, see DefaultContentTypeFilter. // // Setting this will override default and any previous Content Type settings. func ContentTypes(types []string) option { return func(c *config) { var contentTypes []parsedContentType for _, v := range types { mediaType, params, err := mime.ParseMediaType(v) if err == nil { contentTypes = append(contentTypes, parsedContentType{mediaType, params}) } } c.contentTypes = func(ct string) bool { return handleContentType(contentTypes, ct) } } } // ExceptContentTypes specifies a list of content types to compare // the Content-Type header to before compressing. If none // match, the response will be compressed. // // Content types are compared in a case-insensitive, whitespace-ignored // manner. // // A MIME type without any other directive will match a content type // that has the same MIME type, regardless of that content type's other // directives. I.e., "text/html" will match both "text/html" and // "text/html; charset=utf-8". // // A MIME type with any other directive will only match a content type // that has the same MIME type and other directives. I.e., // "text/html; charset=utf-8" will only match "text/html; charset=utf-8". // // By default common compressed audio, video and archive formats, see DefaultContentTypeFilter. // // Setting this will override default and any previous Content Type settings. func ExceptContentTypes(types []string) option { return func(c *config) { var contentTypes []parsedContentType for _, v := range types { mediaType, params, err := mime.ParseMediaType(v) if err == nil { contentTypes = append(contentTypes, parsedContentType{mediaType, params}) } } c.contentTypes = func(ct string) bool { return !handleContentType(contentTypes, ct) } } } // KeepAcceptRanges will keep Accept-Ranges header on gzipped responses. // This will likely break ranged requests since that cannot be transparently // handled by the filter. func KeepAcceptRanges() option { return func(c *config) { c.keepAcceptRanges = true } } // ContentTypeFilter allows adding a custom content type filter. // // The supplied function must return true/false to indicate if content // should be compressed. // // When called no parsing of the content type 'ct' has been done. // It may have been set or auto-detected. // // Setting this will override default and any previous Content Type settings. func ContentTypeFilter(compress func(ct string) bool) option { return func(c *config) { c.contentTypes = compress } } // SuffixETag adds the specified suffix to the ETag header (if it exists) of // responses which are compressed. // // Per [RFC 7232 Section 2.3.3](https://www.rfc-editor.org/rfc/rfc7232#section-2.3.3), // the ETag of a compressed response must differ from it's uncompressed version. // // A suffix such as "-gzip" is sometimes used as a workaround for generating a // unique new ETag (see https://bz.apache.org/bugzilla/show_bug.cgi?id=39727). func SuffixETag(suffix string) option { return func(c *config) { c.suffixETag = suffix } } // DropETag removes the ETag of responses which are compressed. If DropETag is // specified in conjunction with SuffixETag, this option will take precedence // and the ETag will be dropped. // // Per [RFC 7232 Section 2.3.3](https://www.rfc-editor.org/rfc/rfc7232#section-2.3.3), // the ETag of a compressed response must differ from it's uncompressed version. // // This workaround eliminates ETag conflicts between the compressed and // uncompressed versions by removing the ETag from the compressed version. func DropETag() option { return func(c *config) { c.dropETag = true } } // RandomJitter adds 1->n random bytes to output based on checksum of payload. // Specify the amount of input to buffer before applying jitter. // This should cover the sensitive part of your response. // This can be used to obfuscate the exact compressed size. // Specifying 0 will use a buffer size of 64KB. // 'paranoid' will use a slower hashing function, that MAY provide more safety. // See README.md for more information. // If a negative buffer is given, the amount of jitter will not be content dependent. // This provides *less* security than applying content based jitter. func RandomJitter(n, buffer int, paranoid bool) option { return func(c *config) { if n > 0 { c.sha256Jitter = paranoid c.randomJitter = strings.Repeat("Padding-", 1+(n/8))[:n+1] c.jitterBuffer = buffer if c.jitterBuffer == 0 { c.jitterBuffer = 64 << 10 } } else { c.randomJitter = "" c.jitterBuffer = 0 } } } // acceptsGzip returns true if the given HTTP request indicates that it will // accept a gzipped response. func acceptsGzip(r *http.Request) bool { // Note that we don't request this for HEAD requests, // due to a bug in nginx: // https://trac.nginx.org/nginx/ticket/358 // https://golang.org/issue/5522 return r.Method != http.MethodHead && parseEncodingGzip(r.Header.Get(acceptEncoding)) > 0 } // returns true if we've been configured to compress the specific content type. func handleContentType(contentTypes []parsedContentType, ct string) bool { // If contentTypes is empty we handle all content types. if len(contentTypes) == 0 { return true } mediaType, params, err := mime.ParseMediaType(ct) if err != nil { return false } for _, c := range contentTypes { if c.equals(mediaType, params) { return true } } return false } // parseEncodingGzip returns the qvalue of gzip compression. func parseEncodingGzip(s string) float64 { s = strings.TrimSpace(s) for len(s) > 0 { stop := strings.IndexByte(s, ',') if stop < 0 { stop = len(s) } coding, qvalue, _ := parseCoding(s[:stop]) if coding == "gzip" { return qvalue } if stop == len(s) { break } s = s[stop+1:] } return 0 } func parseEncodings(s string) (codings, error) { split := strings.Split(s, ",") c := make(codings, len(split)) var e []string for _, ss := range split { coding, qvalue, err := parseCoding(ss) if err != nil { e = append(e, err.Error()) } else { c[coding] = qvalue } } // TODO (adammck): Use a proper multi-error struct, so the individual errors // can be extracted if anyone cares. if len(e) > 0 { return c, fmt.Errorf("errors while parsing encodings: %s", strings.Join(e, ", ")) } return c, nil } var errEmptyEncoding = errors.New("empty content-coding") // parseCoding parses a single coding (content-coding with an optional qvalue), // as might appear in an Accept-Encoding header. It attempts to forgive minor // formatting errors. func parseCoding(s string) (coding string, qvalue float64, err error) { // Avoid splitting if we can... if len(s) == 0 { return "", 0, errEmptyEncoding } if !strings.ContainsRune(s, ';') { coding = strings.ToLower(strings.TrimSpace(s)) if coding == "" { err = errEmptyEncoding } return coding, DefaultQValue, err } for n, part := range strings.Split(s, ";") { part = strings.TrimSpace(part) qvalue = DefaultQValue if n == 0 { coding = strings.ToLower(part) } else if strings.HasPrefix(part, "q=") { qvalue, err = strconv.ParseFloat(strings.TrimPrefix(part, "q="), 64) if qvalue < 0.0 { qvalue = 0.0 } else if qvalue > 1.0 { qvalue = 1.0 } } } if coding == "" { err = errEmptyEncoding } return } // Don't compress any audio/video types. var excludePrefixDefault = []string{"video/", "audio/", "image/jp"} // Skip a bunch of compressed types that contains this string. // Curated by supposedly still active formats on https://en.wikipedia.org/wiki/List_of_archive_formats var excludeContainsDefault = []string{"compress", "zip", "snappy", "lzma", "xz", "zstd", "brotli", "stuffit"} // DefaultContentTypeFilter excludes common compressed audio, video and archive formats. func DefaultContentTypeFilter(ct string) bool { ct = strings.TrimSpace(strings.ToLower(ct)) if ct == "" { return true } for _, s := range excludeContainsDefault { if strings.Contains(ct, s) { return false } } for _, prefix := range excludePrefixDefault { if strings.HasPrefix(ct, prefix) { return false } } return true } // CompressAllContentTypeFilter will compress all mime types. func CompressAllContentTypeFilter(ct string) bool { return true } const intSize = 32 << (^uint(0) >> 63) // atoi is equivalent to ParseInt(s, 10, 0), converted to type int. func atoi(s string) (int, bool) { if len(s) == 0 { return 0, false } sLen := len(s) if intSize == 32 && (0 < sLen && sLen < 10) || intSize == 64 && (0 < sLen && sLen < 19) { // Fast path for small integers that fit int type. s0 := s if s[0] == '-' || s[0] == '+' { s = s[1:] if len(s) < 1 { return 0, false } } n := 0 for _, ch := range []byte(s) { ch -= '0' if ch > 9 { return 0, false } n = n*10 + int(ch) } if s0[0] == '-' { n = -n } return n, true } // Slow path for invalid, big, or underscored integers. i64, err := strconv.ParseInt(s, 10, 0) return int(i64), err == nil } type unwrapper interface { Unwrap() http.ResponseWriter } // newNoGzipResponseWriter will return a response writer that // cleans up compression artifacts. // Depending on whether http.Hijacker is supported the returned will as well. func newNoGzipResponseWriter(w http.ResponseWriter) http.ResponseWriter { n := &NoGzipResponseWriter{ResponseWriter: w} if hj, ok := w.(http.Hijacker); ok { x := struct { http.ResponseWriter http.Hijacker http.Flusher unwrapper }{ ResponseWriter: n, Hijacker: hj, Flusher: n, unwrapper: n, } return x } return n } // NoGzipResponseWriter filters out HeaderNoCompression. type NoGzipResponseWriter struct { http.ResponseWriter hdrCleaned bool } func (n *NoGzipResponseWriter) CloseNotify() <-chan bool { if cn, ok := n.ResponseWriter.(http.CloseNotifier); ok { return cn.CloseNotify() } return nil } func (n *NoGzipResponseWriter) Flush() { if !n.hdrCleaned { n.ResponseWriter.Header().Del(HeaderNoCompression) n.hdrCleaned = true } if f, ok := n.ResponseWriter.(http.Flusher); ok { f.Flush() } } func (n *NoGzipResponseWriter) Header() http.Header { return n.ResponseWriter.Header() } func (n *NoGzipResponseWriter) Write(bytes []byte) (int, error) { if !n.hdrCleaned { n.ResponseWriter.Header().Del(HeaderNoCompression) n.hdrCleaned = true } return n.ResponseWriter.Write(bytes) } func (n *NoGzipResponseWriter) WriteHeader(statusCode int) { if !n.hdrCleaned { n.ResponseWriter.Header().Del(HeaderNoCompression) n.hdrCleaned = true } n.ResponseWriter.WriteHeader(statusCode) } func (n *NoGzipResponseWriter) Unwrap() http.ResponseWriter { return n.ResponseWriter }