// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package zlib import ( "compress/flate" "fmt" "hash" "hash/adler32" "io" ) // These constants are copied from the flate package, so that code that imports // "compress/zlib" does not also have to import "compress/flate". const ( NoCompression = flate.NoCompression BestSpeed = flate.BestSpeed BestCompression = flate.BestCompression DefaultCompression = flate.DefaultCompression HuffmanOnly = flate.HuffmanOnly ) // A Writer takes data written to it and writes the compressed // form of that data to an underlying writer (see NewWriter). type Writer struct { w io.Writer level int dict []byte compressor *flate.Writer digest hash.Hash32 err error scratch [4]byte wroteHeader bool } // NewWriter creates a new Writer. // Writes to the returned Writer are compressed and written to w. // // It is the caller's responsibility to call Close on the WriteCloser when done. // Writes may be buffered and not flushed until Close. func NewWriter(w io.Writer) *Writer { z, _ := NewWriterLevelDict(w, DefaultCompression, nil) return z } // NewWriterLevel is like NewWriter but specifies the compression level instead // of assuming DefaultCompression. // // The compression level can be DefaultCompression, NoCompression, HuffmanOnly // or any integer value between BestSpeed and BestCompression inclusive. // The error returned will be nil if the level is valid. func NewWriterLevel(w io.Writer, level int) (*Writer, error) { return NewWriterLevelDict(w, level, nil) } // NewWriterLevelDict is like NewWriterLevel but specifies a dictionary to // compress with. // // The dictionary may be nil. If not, its contents should not be modified until // the Writer is closed. func NewWriterLevelDict(w io.Writer, level int, dict []byte) (*Writer, error) { if level < HuffmanOnly || level > BestCompression { return nil, fmt.Errorf("zlib: invalid compression level: %d", level) } return &Writer{ w: w, level: level, dict: dict, }, nil } // Reset clears the state of the Writer z such that it is equivalent to its // initial state from NewWriterLevel or NewWriterLevelDict, but instead writing // to w. func (z *Writer) Reset(w io.Writer) { z.w = w // z.level and z.dict left unchanged. if z.compressor != nil { z.compressor.Reset(w) } if z.digest != nil { z.digest.Reset() } z.err = nil z.scratch = [4]byte{} z.wroteHeader = false } // writeHeader writes the ZLIB header. func (z *Writer) writeHeader() (err error) { z.wroteHeader = true // ZLIB has a two-byte header (as documented in RFC 1950). // The first four bits is the CINFO (compression info), which is 7 for the default deflate window size. // The next four bits is the CM (compression method), which is 8 for deflate. z.scratch[0] = 0x78 // The next two bits is the FLEVEL (compression level). The four values are: // 0=fastest, 1=fast, 2=default, 3=best. // The next bit, FDICT, is set if a dictionary is given. // The final five FCHECK bits form a mod-31 checksum. switch z.level { case -2, 0, 1: z.scratch[1] = 0 << 6 case 2, 3, 4, 5: z.scratch[1] = 1 << 6 case 6, -1: z.scratch[1] = 2 << 6 case 7, 8, 9: z.scratch[1] = 3 << 6 default: panic("unreachable") } if z.dict != nil { z.scratch[1] |= 1 << 5 } z.scratch[1] += uint8(31 - (uint16(z.scratch[0])<<8+uint16(z.scratch[1]))%31) if _, err = z.w.Write(z.scratch[0:2]); err != nil { return err } if z.dict != nil { // The next four bytes are the Adler-32 checksum of the dictionary. checksum := adler32.Checksum(z.dict) z.scratch[0] = uint8(checksum >> 24) z.scratch[1] = uint8(checksum >> 16) z.scratch[2] = uint8(checksum >> 8) z.scratch[3] = uint8(checksum >> 0) if _, err = z.w.Write(z.scratch[0:4]); err != nil { return err } } if z.compressor == nil { // Initialize deflater unless the Writer is being reused // after a Reset call. z.compressor, err = flate.NewWriterDict(z.w, z.level, z.dict) if err != nil { return err } z.digest = adler32.New() } return nil } // Write writes a compressed form of p to the underlying io.Writer. The // compressed bytes are not necessarily flushed until the Writer is closed or // explicitly flushed. func (z *Writer) Write(p []byte) (n int, err error) { if !z.wroteHeader { z.err = z.writeHeader() } if z.err != nil { return 0, z.err } if len(p) == 0 { return 0, nil } n, err = z.compressor.Write(p) if err != nil { z.err = err return } z.digest.Write(p) return } // Flush flushes the Writer to its underlying io.Writer. func (z *Writer) Flush() error { if !z.wroteHeader { z.err = z.writeHeader() } if z.err != nil { return z.err } z.err = z.compressor.Flush() return z.err } // Close closes the Writer, flushing any unwritten data to the underlying // io.Writer, but does not close the underlying io.Writer. func (z *Writer) Close() error { if !z.wroteHeader { z.err = z.writeHeader() } if z.err != nil { return z.err } z.err = z.compressor.Close() if z.err != nil { return z.err } checksum := z.digest.Sum32() // ZLIB (RFC 1950) is big-endian, unlike GZIP (RFC 1952). z.scratch[0] = uint8(checksum >> 24) z.scratch[1] = uint8(checksum >> 16) z.scratch[2] = uint8(checksum >> 8) z.scratch[3] = uint8(checksum >> 0) _, z.err = z.w.Write(z.scratch[0:4]) return z.err }