internal static int inflate_trees_fixed(int[] bl, int[] bd, int[][] tl, int[][] td, ZlibCodec z) { bl[0] = fixed_bl; bd[0] = fixed_bd; tl[0] = fixed_tl; td[0] = fixed_td; return Z_OK; }
private void end() { if (z == null) return; if (_wantCompress) { _z.EndDeflate(); } else { _z.EndInflate(); } _z = null; }
internal int inflate_trees_bits(int[] c, int[] bb, int[] tb, int[] hp, ZlibCodec z) { int result; initWorkArea(19); hn[0] = 0; result = huft_build(c, 0, 19, 19, null, null, tb, bb, hp, hn, v); if (result == Z_DATA_ERROR) { z.Message = "oversubscribed dynamic bit lengths tree"; } else if (result == Z_BUF_ERROR || bb[0] == 0) { z.Message = "incomplete dynamic bit lengths tree"; result = Z_DATA_ERROR; } return result; }
internal int inflate_trees_dynamic(int nl, int nd, int[] c, int[] bl, int[] bd, int[] tl, int[] td, int[] hp, ZlibCodec z) { int result; // build literal/length tree initWorkArea(288); hn[0] = 0; result = huft_build(c, 0, nl, 257, cplens, cplext, tl, bl, hp, hn, v); if (result != Z_OK || bl[0] == 0) { if (result == Z_DATA_ERROR) { z.Message = "oversubscribed literal/length tree"; } else if (result != Z_MEM_ERROR) { z.Message = "incomplete literal/length tree"; result = Z_DATA_ERROR; } return result; } // build distance tree initWorkArea(288); result = huft_build(c, nl, nd, 0, cpdist, cpdext, td, bd, hp, hn, v); if (result != Z_OK || (bd[0] == 0 && nl > 257)) { if (result == Z_DATA_ERROR) { z.Message = "oversubscribed distance tree"; } else if (result == Z_BUF_ERROR) { z.Message = "incomplete distance tree"; result = Z_DATA_ERROR; } else if (result != Z_MEM_ERROR) { z.Message = "empty distance tree with lengths"; result = Z_DATA_ERROR; } return result; } return Z_OK; }
internal int Initialize(ZlibCodec codec, CompressionLevel level, int bits, CompressionStrategy compressionStrategy) { return Initialize(codec, level, bits, MEM_LEVEL_DEFAULT, compressionStrategy); }
internal int Initialize(ZlibCodec codec, CompressionLevel level, int windowBits, int memLevel, CompressionStrategy strategy) { _codec = codec; _codec.Message = null; // validation if (windowBits < 9 || windowBits > 15) throw new ZlibException("windowBits must be in the range 9..15."); if (memLevel < 1 || memLevel > MEM_LEVEL_MAX) throw new ZlibException(String.Format("memLevel must be in the range 1.. {0}", MEM_LEVEL_MAX)); _codec.dstate = this; w_bits = windowBits; w_size = 1 << w_bits; w_mask = w_size - 1; hash_bits = memLevel + 7; hash_size = 1 << hash_bits; hash_mask = hash_size - 1; hash_shift = ((hash_bits + MIN_MATCH - 1) / MIN_MATCH); window = new byte[w_size * 2]; prev = new short[w_size]; head = new short[hash_size]; // for memLevel==8, this will be 16384, 16k lit_bufsize = 1 << (memLevel + 6); // Use a single array as the buffer for data pending compression, // the output distance codes, and the output length codes (aka tree). // orig comment: This works just fine since the average // output size for (length,distance) codes is <= 24 bits. pending = new byte[lit_bufsize * 4]; _distanceOffset = lit_bufsize; _lengthOffset = (1 + 2) * lit_bufsize; // So, for memLevel 8, the length of the pending buffer is 65536. 64k. // The first 16k are pending bytes. // The middle slice, of 32k, is used for distance codes. // The final 16k are length codes. this.compressionLevel = level; this.compressionStrategy = strategy; Reset(); return ZlibConstants.Z_OK; }
internal int Initialize(ZlibCodec codec, CompressionLevel level) { return Initialize(codec, level, ZlibConstants.WindowBitsMax); }
// Returns true if inflate is currently at the end of a block generated // by Z_SYNC_FLUSH or Z_FULL_FLUSH. This function is used by one PPP // implementation to provide an additional safety check. PPP uses Z_SYNC_FLUSH // but removes the length bytes of the resulting empty stored block. When // decompressing, PPP checks that at the end of input packet, inflate is // waiting for these length bytes. internal int SyncPoint(ZlibCodec z) { return blocks.SyncPoint(); }
internal int Initialize(ZlibCodec codec, int w) { _codec = codec; _codec.Message = null; blocks = null; // handle undocumented nowrap option (no zlib header or check) //nowrap = 0; //if (w < 0) //{ // w = - w; // nowrap = 1; //} // set window size if (w < 8 || w > 15) { End(); throw new ZlibException("Bad window size."); //return ZlibConstants.Z_STREAM_ERROR; } wbits = w; blocks = new InflateBlocks(codec, HandleRfc1950HeaderBytes ? this : null, 1 << w); // reset state Reset(); return ZlibConstants.Z_OK; }
internal InflateBlocks(ZlibCodec codec, System.Object checkfn, int w) { _codec = codec; hufts = new int[MANY * 3]; window = new byte[w]; end = w; this.checkfn = checkfn; mode = InflateBlockMode.TYPE; Reset(); }
// Called with number of bytes left to write in window at least 258 // (the maximum string length) and number of input bytes available // at least ten. The ten bytes are six bytes for the longest length/ // distance pair plus four bytes for overloading the bit buffer. internal int InflateFast(int bl, int bd, int[] tl, int tl_index, int[] td, int td_index, InflateBlocks s, ZlibCodec z) { int t; // temporary pointer int[] tp; // temporary pointer int tp_index; // temporary pointer int e; // extra bits or operation int b; // bit buffer int k; // bits in bit buffer int p; // input data pointer int n; // bytes available there int q; // output window write pointer int m; // bytes to end of window or read pointer int ml; // mask for literal/length tree int md; // mask for distance tree int c; // bytes to copy int d; // distance back to copy from int r; // copy source pointer int tp_index_t_3; // (tp_index+t)*3 // load input, output, bit values p = z.NextIn; n = z.AvailableBytesIn; b = s.bitb; k = s.bitk; q = s.writeAt; m = q < s.readAt ? s.readAt - q - 1 : s.end - q; // initialize masks ml = InternalInflateConstants.InflateMask[bl]; md = InternalInflateConstants.InflateMask[bd]; // do until not enough input or output space for fast loop do { // assume called with m >= 258 && n >= 10 // get literal/length code while (k < (20)) { // max bits for literal/length code n--; b |= (z.InputBuffer[p++] & 0xff) << k; k += 8; } t = b & ml; tp = tl; tp_index = tl_index; tp_index_t_3 = (tp_index + t) * 3; if ((e = tp[tp_index_t_3]) == 0) { b >>= (tp[tp_index_t_3 + 1]); k -= (tp[tp_index_t_3 + 1]); s.window[q++] = (byte)tp[tp_index_t_3 + 2]; m--; continue; } do { b >>= (tp[tp_index_t_3 + 1]); k -= (tp[tp_index_t_3 + 1]); if ((e & 16) != 0) { e &= 15; c = tp[tp_index_t_3 + 2] + ((int)b & InternalInflateConstants.InflateMask[e]); b >>= e; k -= e; // decode distance base of block to copy while (k < 15) { // max bits for distance code n--; b |= (z.InputBuffer[p++] & 0xff) << k; k += 8; } t = b & md; tp = td; tp_index = td_index; tp_index_t_3 = (tp_index + t) * 3; e = tp[tp_index_t_3]; do { b >>= (tp[tp_index_t_3 + 1]); k -= (tp[tp_index_t_3 + 1]); if ((e & 16) != 0) { // get extra bits to add to distance base e &= 15; while (k < e) { // get extra bits (up to 13) n--; b |= (z.InputBuffer[p++] & 0xff) << k; k += 8; } d = tp[tp_index_t_3 + 2] + (b & InternalInflateConstants.InflateMask[e]); b >>= e; k -= e; // do the copy m -= c; if (q >= d) { // offset before dest // just copy r = q - d; if (q - r > 0 && 2 > (q - r)) { s.window[q++] = s.window[r++]; // minimum count is three, s.window[q++] = s.window[r++]; // so unroll loop a little c -= 2; } else { Array.Copy(s.window, r, s.window, q, 2); q += 2; r += 2; c -= 2; } } else { // else offset after destination r = q - d; do { r += s.end; // force pointer in window } while (r < 0); // covers invalid distances e = s.end - r; if (c > e) { // if source crosses, c -= e; // wrapped copy if (q - r > 0 && e > (q - r)) { do { s.window[q++] = s.window[r++]; } while (--e != 0); } else { Array.Copy(s.window, r, s.window, q, e); q += e; r += e; e = 0; } r = 0; // copy rest from start of window } } // copy all or what's left if (q - r > 0 && c > (q - r)) { do { s.window[q++] = s.window[r++]; } while (--c != 0); } else { Array.Copy(s.window, r, s.window, q, c); q += c; r += c; c = 0; } break; } else if ((e & 64) == 0) { t += tp[tp_index_t_3 + 2]; t += (b & InternalInflateConstants.InflateMask[e]); tp_index_t_3 = (tp_index + t) * 3; e = tp[tp_index_t_3]; } else { z.Message = "invalid distance code"; c = z.AvailableBytesIn - n; c = (k >> 3) < c ? k >> 3 : c; n += c; p -= c; k -= (c << 3); s.bitb = b; s.bitk = k; z.AvailableBytesIn = n; z.TotalBytesIn += p - z.NextIn; z.NextIn = p; s.writeAt = q; return ZlibConstants.Z_DATA_ERROR; } } while (true); break; } if ((e & 64) == 0) { t += tp[tp_index_t_3 + 2]; t += (b & InternalInflateConstants.InflateMask[e]); tp_index_t_3 = (tp_index + t) * 3; if ((e = tp[tp_index_t_3]) == 0) { b >>= (tp[tp_index_t_3 + 1]); k -= (tp[tp_index_t_3 + 1]); s.window[q++] = (byte)tp[tp_index_t_3 + 2]; m--; break; } } else if ((e & 32) != 0) { c = z.AvailableBytesIn - n; c = (k >> 3) < c ? k >> 3 : c; n += c; p -= c; k -= (c << 3); s.bitb = b; s.bitk = k; z.AvailableBytesIn = n; z.TotalBytesIn += p - z.NextIn; z.NextIn = p; s.writeAt = q; return ZlibConstants.Z_STREAM_END; } else { z.Message = "invalid literal/length code"; c = z.AvailableBytesIn - n; c = (k >> 3) < c ? k >> 3 : c; n += c; p -= c; k -= (c << 3); s.bitb = b; s.bitk = k; z.AvailableBytesIn = n; z.TotalBytesIn += p - z.NextIn; z.NextIn = p; s.writeAt = q; return ZlibConstants.Z_DATA_ERROR; } } while (true); } while (m >= 258 && n >= 10); // not enough input or output--restore pointers and return c = z.AvailableBytesIn - n; c = (k >> 3) < c ? k >> 3 : c; n += c; p -= c; k -= (c << 3); s.bitb = b; s.bitk = k; z.AvailableBytesIn = n; z.TotalBytesIn += p - z.NextIn; z.NextIn = p; s.writeAt = q; return ZlibConstants.Z_OK; }