SamsonGame/dll_src/crc/crc.cs

using System;
using System.IO;
using System.Collections.Generic;
using System.Security.Cryptography;

/// <summary>
/// Implements a 32-bit CRC hash algorithm compatible with Zip etc.
/// </summary>
/// <remarks>
/// Crc32 should only be used for backward compatibility with older file formats
/// and algorithms. It is not secure enough for new applications.
/// If you need to call multiple times for the same data either use the HashAlgorithm
/// interface or remember that the result of one Compute call needs to be ~ (XOR) before
/// being passed in as the seed for the next Compute call.
/// </remarks>
public sealed class Crc32 : HashAlgorithm
{
  public const UInt32 DefaultPolynomial = 0xedb88320u;
  public const UInt32 DefaultSeed = 0xffffffffu;

  private static UInt32[] defaultTable;

  private readonly UInt32 seed;
  private readonly UInt32[] table;
  private UInt32 hash;

  public Crc32()
    : this(DefaultPolynomial, DefaultSeed)
  {
  }

  public Crc32(UInt32 polynomial, UInt32 seed)
  {
    table = InitializeTable(polynomial);
    this.seed = hash = seed;
  }

  public override void Initialize()
  {
    hash = seed;
  }

  protected override void HashCore(byte[] buffer, int start, int length)
  {
    hash = CalculateHash(table, hash, buffer, start, length);
  }

  protected override byte[] HashFinal()
  {
    var hashBuffer = UInt32ToBigEndianBytes(~hash);
    HashValue = hashBuffer;
    return hashBuffer;
  }

  public override int HashSize { get { return 32; } }

  public static UInt32 Compute(byte[] buffer, int buffer_len)
  {
    return Compute(DefaultSeed, buffer, buffer_len);
  }

  public static UInt32 Compute(UInt32 seed, byte[] buffer, int buffer_len)
  {
    return Compute(DefaultPolynomial, seed, buffer, buffer_len);
  }

  public static UInt32 Compute(UInt32 polynomial, UInt32 seed, byte[] buffer, int buffer_len)
  {
    return ~CalculateHash(InitializeTable(polynomial), seed, buffer, 0, buffer_len);
  }

  public static UInt32 Compute(Stream s)
  {
    return Compute(DefaultSeed, s);
  }

  public static UInt32 Compute(UInt32 seed, Stream s)
  {
    return Compute(DefaultPolynomial, seed, s);
  }

  public static UInt32 Compute(UInt32 polynomial, UInt32 seed, Stream s)
  {
    return ~CalculateHash(InitializeTable(polynomial), seed, s);
  }

  private static UInt32[] InitializeTable(UInt32 polynomial)
  {
    if (polynomial == DefaultPolynomial && defaultTable != null)
      return defaultTable;

    var createTable = new UInt32[256];
    for (var i = 0; i < 256; i++)
    {
      var entry = (UInt32)i;
      for (var j = 0; j < 8; j++)
        if ((entry & 1) == 1)
          entry = (entry >> 1) ^ polynomial;
        else
          entry = entry >> 1;
      createTable[i] = entry;
    }

    if (polynomial == DefaultPolynomial)
      defaultTable = createTable;

    return createTable;
  }

  private static UInt32 CalculateHash(UInt32[] table, UInt32 seed, byte[] buffer, int start, int size)
  {
    var crc = seed;
    for (var i = start; i < size - start; i++)
      crc = (crc >> 8) ^ table[buffer[i] ^ crc & 0xff];
    return crc;
  }

  private static UInt32 CalculateHash(UInt32[] table, UInt32 seed, Stream s)
  {
    var crc = seed;

    byte[] bytes = new byte[4 * 1024];

    int bytes_to_read = (int)(s.Length - s.Position);
    while(bytes_to_read > 0)
    {
      int n = s.Read(bytes, 0, bytes.Length);
      bytes_to_read -= n;
      crc = CalculateHash(table, crc, bytes, 0, n);
    }
    return crc;
  }

  public static UInt32 BeginHash()
  {
    var crc = DefaultSeed;
    return crc;
  }

  public static UInt32 AddHash(UInt32 crc, byte data)
  {
    UInt32[] table = InitializeTable(DefaultPolynomial);
    crc = (crc >> 8) ^ table[data ^ crc & 0xff];
    return crc;
  }

  public static UInt32 AddHash(UInt32 crc, short data)
  {
    crc = AddHash(crc, (byte)(data & 0xFF));
    crc = AddHash(crc, (byte)((data >> 8) & 0xFF));
    return crc;
  }

  public static UInt32 AddHash(UInt32 crc, UInt32 data)
  {
    crc = AddHash(crc, (byte)(data & 0xFF));
    crc = AddHash(crc, (byte)((data >> 8) & 0xFF));
    crc = AddHash(crc, (byte)((data >> 16) & 0xFF));
    crc = AddHash(crc, (byte)((data >> 24) & 0xFF));
    return crc;
  }

  public static UInt32 FinalizeHash(UInt32 crc)
  {
    return ~crc;
  }

  //Convenience shortcut
  public static uint CalcChecksum(uint data1, uint data2)
  {
    uint checksum = Crc32.BeginHash();
    checksum = Crc32.AddHash(checksum, data1);
    checksum = Crc32.AddHash(checksum, data2);
    checksum = Crc32.FinalizeHash(checksum);
    return checksum;
  }

  //Convenience shortcut
  public static uint CalcChecksum(ulong data1, ulong data2)
  {
    uint checksum = Crc32.BeginHash();
    checksum = Crc32.AddHash(checksum, (uint)(data1 >> 32));
    checksum = Crc32.AddHash(checksum, (uint)(data1 & 0xFFFFFFFFL));
    checksum = Crc32.AddHash(checksum, (uint)(data2 >> 32));
    checksum = Crc32.AddHash(checksum, (uint)(data2 & 0xFFFFFFFFL));
    checksum = Crc32.FinalizeHash(checksum);
    return checksum;
  }

  //Convenience shortcut
  public static uint CalcChecksum(ulong data)
  {
    uint checksum = Crc32.BeginHash();
    checksum = Crc32.AddHash(checksum, (uint)(data >> 32));
    checksum = Crc32.AddHash(checksum, (uint)(data & 0xFFFFFFFFL));
    checksum = Crc32.FinalizeHash(checksum);
    return checksum;
  }

  //Convenience shortcut
  public static uint CalcChecksum(long data)
  {
    return CalcChecksum((ulong)data);
  }

  private static byte[] UInt32ToBigEndianBytes(UInt32 uint32)
  {
    var result = BitConverter.GetBytes(uint32);

    if (BitConverter.IsLittleEndian)
      Array.Reverse(result);

    return result;
  }
}

public sealed class Adler32
{
  // largest prime smaller than 65536
  private const int BASE = 65521;
  // NMAX is the largest n such that 255n(n+1)/2 + (n+1)(BASE-1) <= 2^32-1
  private const int NMAX = 5552;
  
  static public long Compute(long adler, byte[] buf, int index, int len)
  {
      if (buf == null)
      {
          return 1L;
      }
        
      long s1 = adler & 0xffff;
      long s2 = (adler >> 16) & 0xffff;
      int k;
        
      while (len > 0)
      {
          k = len < NMAX?len:NMAX;
          len -= k;
          while (k >= 16)
          {
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              s1 += (buf[index++] & 0xff); s2 += s1;
              k -= 16;
          }
          if (k != 0)
          {
              do
              {
                  s1 += (buf[index++] & 0xff); s2 += s1;
              }
              while (--k != 0);
          }
          s1 %= BASE;
          s2 %= BASE;
      }
      return (s2 << 16) | s1;
  }

  static public long Compute(long adler, Stream buf)
  {
      if (buf == null)
      {
          return 1L;
      }
        
      long pos = buf.Position;
      long s1 = adler & 0xffff;
      long s2 = (adler >> 16) & 0xffff;
      int k;
        
      int len = (int)(buf.Length - pos);
      while (len > 0)
      {
          k = len < NMAX ? len : NMAX;
          len -= k;
          while (k >= 16)
          {
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              s1 += (buf.ReadByte() & 0xff); s2 += s1;
              k -= 16;
          }
          if (k != 0)
          {
              do
              {
                  s1 += (buf.ReadByte() & 0xff); s2 += s1;
              }
              while (--k != 0);
          }
          s1 %= BASE;
          s2 %= BASE;
      }
      buf.Position = pos;
      return (s2 << 16) | s1;
  }
}
Initial commit 2021-12-29 20:50:11 +03:00			`using System;`
			`using System.IO;`
			`using System.Collections.Generic;`
			`using System.Security.Cryptography;`

			`/// <summary>`
			`/// Implements a 32-bit CRC hash algorithm compatible with Zip etc.`
			`/// </summary>`
			`/// <remarks>`
			`/// Crc32 should only be used for backward compatibility with older file formats`
			`/// and algorithms. It is not secure enough for new applications.`
			`/// If you need to call multiple times for the same data either use the HashAlgorithm`
			`/// interface or remember that the result of one Compute call needs to be ~ (XOR) before`
			`/// being passed in as the seed for the next Compute call.`
			`/// </remarks>`
			`public sealed class Crc32 : HashAlgorithm`
			`{`
			`public const UInt32 DefaultPolynomial = 0xedb88320u;`
			`public const UInt32 DefaultSeed = 0xffffffffu;`

			`private static UInt32[] defaultTable;`

			`private readonly UInt32 seed;`
			`private readonly UInt32[] table;`
			`private UInt32 hash;`

			`public Crc32()`
			`: this(DefaultPolynomial, DefaultSeed)`
			`{`
			`}`

			`public Crc32(UInt32 polynomial, UInt32 seed)`
			`{`
			`table = InitializeTable(polynomial);`
			`this.seed = hash = seed;`
			`}`

			`public override void Initialize()`
			`{`
			`hash = seed;`
			`}`

			`protected override void HashCore(byte[] buffer, int start, int length)`
			`{`
			`hash = CalculateHash(table, hash, buffer, start, length);`
			`}`

			`protected override byte[] HashFinal()`
			`{`
			`var hashBuffer = UInt32ToBigEndianBytes(~hash);`
			`HashValue = hashBuffer;`
			`return hashBuffer;`
			`}`

			`public override int HashSize { get { return 32; } }`

			`public static UInt32 Compute(byte[] buffer, int buffer_len)`
			`{`
			`return Compute(DefaultSeed, buffer, buffer_len);`
			`}`

			`public static UInt32 Compute(UInt32 seed, byte[] buffer, int buffer_len)`
			`{`
			`return Compute(DefaultPolynomial, seed, buffer, buffer_len);`
			`}`

			`public static UInt32 Compute(UInt32 polynomial, UInt32 seed, byte[] buffer, int buffer_len)`
			`{`
			`return ~CalculateHash(InitializeTable(polynomial), seed, buffer, 0, buffer_len);`
			`}`

			`public static UInt32 Compute(Stream s)`
			`{`
			`return Compute(DefaultSeed, s);`
			`}`

			`public static UInt32 Compute(UInt32 seed, Stream s)`
			`{`
			`return Compute(DefaultPolynomial, seed, s);`
			`}`

			`public static UInt32 Compute(UInt32 polynomial, UInt32 seed, Stream s)`
			`{`
			`return ~CalculateHash(InitializeTable(polynomial), seed, s);`
			`}`

			`private static UInt32[] InitializeTable(UInt32 polynomial)`
			`{`
			`if (polynomial == DefaultPolynomial && defaultTable != null)`
			`return defaultTable;`

			`var createTable = new UInt32[256];`
			`for (var i = 0; i < 256; i++)`
			`{`
			`var entry = (UInt32)i;`
			`for (var j = 0; j < 8; j++)`
			`if ((entry & 1) == 1)`
			`entry = (entry >> 1) ^ polynomial;`
			`else`
			`entry = entry >> 1;`
			`createTable[i] = entry;`
			`}`

			`if (polynomial == DefaultPolynomial)`
			`defaultTable = createTable;`

			`return createTable;`
			`}`

			`private static UInt32 CalculateHash(UInt32[] table, UInt32 seed, byte[] buffer, int start, int size)`
			`{`
			`var crc = seed;`
			`for (var i = start; i < size - start; i++)`
			`crc = (crc >> 8) ^ table[buffer[i] ^ crc & 0xff];`
			`return crc;`
			`}`

			`private static UInt32 CalculateHash(UInt32[] table, UInt32 seed, Stream s)`
			`{`
			`var crc = seed;`

			`byte[] bytes = new byte[4 * 1024];`

			`int bytes_to_read = (int)(s.Length - s.Position);`
			`while(bytes_to_read > 0)`
			`{`
			`int n = s.Read(bytes, 0, bytes.Length);`
			`bytes_to_read -= n;`
			`crc = CalculateHash(table, crc, bytes, 0, n);`
			`}`
			`return crc;`
			`}`

			`public static UInt32 BeginHash()`
			`{`
			`var crc = DefaultSeed;`
			`return crc;`
			`}`

			`public static UInt32 AddHash(UInt32 crc, byte data)`
			`{`
			`UInt32[] table = InitializeTable(DefaultPolynomial);`
			`crc = (crc >> 8) ^ table[data ^ crc & 0xff];`
			`return crc;`
			`}`

			`public static UInt32 AddHash(UInt32 crc, short data)`
			`{`
			`crc = AddHash(crc, (byte)(data & 0xFF));`
			`crc = AddHash(crc, (byte)((data >> 8) & 0xFF));`
			`return crc;`
			`}`

			`public static UInt32 AddHash(UInt32 crc, UInt32 data)`
			`{`
			`crc = AddHash(crc, (byte)(data & 0xFF));`
			`crc = AddHash(crc, (byte)((data >> 8) & 0xFF));`
			`crc = AddHash(crc, (byte)((data >> 16) & 0xFF));`
			`crc = AddHash(crc, (byte)((data >> 24) & 0xFF));`
			`return crc;`
			`}`

			`public static UInt32 FinalizeHash(UInt32 crc)`
			`{`
			`return ~crc;`
			`}`

			`//Convenience shortcut`
			`public static uint CalcChecksum(uint data1, uint data2)`
			`{`
			`uint checksum = Crc32.BeginHash();`
			`checksum = Crc32.AddHash(checksum, data1);`
			`checksum = Crc32.AddHash(checksum, data2);`
			`checksum = Crc32.FinalizeHash(checksum);`
			`return checksum;`
			`}`

			`//Convenience shortcut`
			`public static uint CalcChecksum(ulong data1, ulong data2)`
			`{`
			`uint checksum = Crc32.BeginHash();`
			`checksum = Crc32.AddHash(checksum, (uint)(data1 >> 32));`
			`checksum = Crc32.AddHash(checksum, (uint)(data1 & 0xFFFFFFFFL));`
			`checksum = Crc32.AddHash(checksum, (uint)(data2 >> 32));`
			`checksum = Crc32.AddHash(checksum, (uint)(data2 & 0xFFFFFFFFL));`
			`checksum = Crc32.FinalizeHash(checksum);`
			`return checksum;`
			`}`

			`//Convenience shortcut`
			`public static uint CalcChecksum(ulong data)`
			`{`
			`uint checksum = Crc32.BeginHash();`
			`checksum = Crc32.AddHash(checksum, (uint)(data >> 32));`
			`checksum = Crc32.AddHash(checksum, (uint)(data & 0xFFFFFFFFL));`
			`checksum = Crc32.FinalizeHash(checksum);`
			`return checksum;`
			`}`

			`//Convenience shortcut`
			`public static uint CalcChecksum(long data)`
			`{`
			`return CalcChecksum((ulong)data);`
			`}`

			`private static byte[] UInt32ToBigEndianBytes(UInt32 uint32)`
			`{`
			`var result = BitConverter.GetBytes(uint32);`

			`if (BitConverter.IsLittleEndian)`
			`Array.Reverse(result);`

			`return result;`
			`}`
			`}`

			`public sealed class Adler32`
			`{`
			`// largest prime smaller than 65536`
			`private const int BASE = 65521;`
			`// NMAX is the largest n such that 255n(n+1)/2 + (n+1)(BASE-1) <= 2^32-1`
			`private const int NMAX = 5552;`

			`static public long Compute(long adler, byte[] buf, int index, int len)`
			`{`
			`if (buf == null)`
			`{`
			`return 1L;`
			`}`

			`long s1 = adler & 0xffff;`
			`long s2 = (adler >> 16) & 0xffff;`
			`int k;`

			`while (len > 0)`
			`{`
			`k = len < NMAX?len:NMAX;`
			`len -= k;`
			`while (k >= 16)`
			`{`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`k -= 16;`
			`}`
			`if (k != 0)`
			`{`
			`do`
			`{`
			`s1 += (buf[index++] & 0xff); s2 += s1;`
			`}`
			`while (--k != 0);`
			`}`
			`s1 %= BASE;`
			`s2 %= BASE;`
			`}`
			`return (s2 << 16) \| s1;`
			`}`

			`static public long Compute(long adler, Stream buf)`
			`{`
			`if (buf == null)`
			`{`
			`return 1L;`
			`}`

			`long pos = buf.Position;`
			`long s1 = adler & 0xffff;`
			`long s2 = (adler >> 16) & 0xffff;`
			`int k;`

			`int len = (int)(buf.Length - pos);`
			`while (len > 0)`
			`{`
			`k = len < NMAX ? len : NMAX;`
			`len -= k;`
			`while (k >= 16)`
			`{`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`k -= 16;`
			`}`
			`if (k != 0)`
			`{`
			`do`
			`{`
			`s1 += (buf.ReadByte() & 0xff); s2 += s1;`
			`}`
			`while (--k != 0);`
			`}`
			`s1 %= BASE;`
			`s2 %= BASE;`
			`}`
			`buf.Position = pos;`
			`return (s2 << 16) \| s1;`
			`}`
			`}`