Extract WavReader to own file and move it to FileFormats

2016-06-23 23:47:14 +02:00
parent f1882e2dd6
commit 61acbe70d6
3 changed files with 181 additions and 164 deletions
--- a/OpenRA.Mods.Common/AudioLoaders/WavLoader.cs
+++ b/OpenRA.Mods.Common/AudioLoaders/WavLoader.cs
@@ -82,168 +82,4 @@ namespace OpenRA.Mods.Common.AudioLoaders
 			});
 		}
 	}
 	public class WavReader
 	{
 		public int FileSize;
 		public string Format;
 		public int FmtChunkSize;
 		public int AudioFormat;
 		public int Channels;
 		public int SampleRate;
 		public int ByteRate;
 		public int BlockAlign;
 		public int BitsPerSample;
 		public int UncompressedSize;
 		public int DataSize;
 		public byte[] RawOutput;
 		public enum WaveType { Pcm = 0x1, ImaAdpcm = 0x11 }
 		public static WaveType Type { get; private set; }
 		public bool LoadSound(Stream s)
 		{
 			var type = s.ReadASCII(4);
 			if (type != "RIFF")
 				return false;
 			FileSize = s.ReadInt32();
 			Format = s.ReadASCII(4);
 			if (Format != "WAVE")
 				return false;
 			while (s.Position < s.Length)
 			{
 				if ((s.Position & 1) == 1)
 					s.ReadByte(); // Alignment
 				type = s.ReadASCII(4);
 				switch (type)
 				{
 					case "fmt ":
 						FmtChunkSize = s.ReadInt32();
 						AudioFormat = s.ReadInt16();
 						Type = (WaveType)AudioFormat;
 						if (!Enum.IsDefined(typeof(WaveType), Type))
 							throw new NotSupportedException("Compression type {0} is not supported.".F(AudioFormat));
 						Channels = s.ReadInt16();
 						SampleRate = s.ReadInt32();
 						ByteRate = s.ReadInt32();
 						BlockAlign = s.ReadInt16();
 						BitsPerSample = s.ReadInt16();
 						s.ReadBytes(FmtChunkSize - 16);
 						break;
 					case "fact":
 						var chunkSize = s.ReadInt32();
 						UncompressedSize = s.ReadInt32();
 						s.ReadBytes(chunkSize - 4);
 						break;
 					case "data":
 						DataSize = s.ReadInt32();
 						RawOutput = s.ReadBytes(DataSize);
 						break;
 					default:
 						var unknownChunkSize = s.ReadInt32();
 						s.ReadBytes(unknownChunkSize);
 						break;
 				}
 			}
 			if (Type == WaveType.ImaAdpcm)
 			{
 				RawOutput = DecodeImaAdpcmData();
 				BitsPerSample = 16;
 			}
 			return true;
 		}
 		public static float WaveLength(Stream s)
 		{
 			s.Position = 12;
 			var fmt = s.ReadASCII(4);
 			if (fmt != "fmt ")
 				return 0;
 			s.Position = 22;
 			var channels = s.ReadInt16();
 			var sampleRate = s.ReadInt32();
 			s.Position = 34;
 			var bitsPerSample = s.ReadInt16();
 			var length = s.Length * 8;
 			return length / (channels * sampleRate * bitsPerSample);
 		}
 		public byte[] DecodeImaAdpcmData()
 		{
 			var s = new MemoryStream(RawOutput);
 			var numBlocks = DataSize / BlockAlign;
 			var blockDataSize = BlockAlign - (Channels * 4);
 			var outputSize = UncompressedSize * Channels * 2;
 			var outOffset = 0;
 			var output = new byte[outputSize];
 			var predictor = new int[Channels];
 			var index = new int[Channels];
 			// Decode each block of IMA ADPCM data in RawOutput
 			for (var block = 0; block < numBlocks; block++)
 			{
 				// Each block starts with a initial state per-channel
 				for (var c = 0; c < Channels; c++)
 				{
 					predictor[c] = s.ReadInt16();
 					index[c] = s.ReadUInt8();
 					/* unknown/reserved */ s.ReadUInt8();
 					// Output first sample from input
 					output[outOffset++] = (byte)predictor[c];
 					output[outOffset++] = (byte)(predictor[c] >> 8);
 					if (outOffset >= outputSize)
 						return output;
 				}
 				// Decode and output remaining data in this block
 				var blockOffset = 0;
 				while (blockOffset < blockDataSize)
 				{
 					for (var c = 0; c < Channels; c++)
 					{
 						// Decode 4 bytes (to 16 bytes of output) per channel
 						var chunk = s.ReadBytes(4);
 						var decoded = ImaAdpcmReader.LoadImaAdpcmSound(chunk, ref index[c], ref predictor[c]);
 						// Interleave output, one sample per channel
 						var outOffsetChannel = outOffset + (2 * c);
 						for (var i = 0; i < decoded.Length; i += 2)
 						{
 							var outOffsetSample = outOffsetChannel + i;
 							if (outOffsetSample >= outputSize)
 								return output;
 							output[outOffsetSample] = decoded[i];
 							output[outOffsetSample + 1] = decoded[i + 1];
 							outOffsetChannel += 2 * (Channels - 1);
 						}
 						blockOffset += 4;
 					}
 					outOffset += 16 * Channels;
 				}
 			}
 			return output;
 		}
 	}
 }
--- a/OpenRA.Mods.Common/FileFormats/WavReader.cs
+++ b/OpenRA.Mods.Common/FileFormats/WavReader.cs
@@ -0,0 +1,180 @@
 #region Copyright & License Information
 /*
 * Copyright 2007-2016 The OpenRA Developers (see AUTHORS)
 * This file is part of OpenRA, which is free software. It is made
 * available to you under the terms of the GNU General Public License
 * as published by the Free Software Foundation, either version 3 of
 * the License, or (at your option) any later version. For more
 * information, see COPYING.
 */
 #endregion
 using System;
 using System.IO;
 namespace OpenRA.Mods.Common.FileFormats
 {
 	public class WavReader
 	{
 		public int FileSize;
 		public string Format;
 		public int FmtChunkSize;
 		public int AudioFormat;
 		public int Channels;
 		public int SampleRate;
 		public int ByteRate;
 		public int BlockAlign;
 		public int BitsPerSample;
 		public int UncompressedSize;
 		public int DataSize;
 		public byte[] RawOutput;
 		public enum WaveType { Pcm = 0x1, ImaAdpcm = 0x11 }
 		public static WaveType Type { get; private set; }
 		public bool LoadSound(Stream s)
 		{
 			var type = s.ReadASCII(4);
 			if (type != "RIFF")
 				return false;
 			FileSize = s.ReadInt32();
 			Format = s.ReadASCII(4);
 			if (Format != "WAVE")
 				return false;
 			while (s.Position < s.Length)
 			{
 				if ((s.Position & 1) == 1)
 					s.ReadByte(); // Alignment
 				type = s.ReadASCII(4);
 				switch (type)
 				{
 					case "fmt ":
 						FmtChunkSize = s.ReadInt32();
 						AudioFormat = s.ReadInt16();
 						Type = (WaveType)AudioFormat;
 						if (!Enum.IsDefined(typeof(WaveType), Type))
 							throw new NotSupportedException("Compression type {0} is not supported.".F(AudioFormat));
 						Channels = s.ReadInt16();
 						SampleRate = s.ReadInt32();
 						ByteRate = s.ReadInt32();
 						BlockAlign = s.ReadInt16();
 						BitsPerSample = s.ReadInt16();
 						s.ReadBytes(FmtChunkSize - 16);
 						break;
 					case "fact":
 						var chunkSize = s.ReadInt32();
 						UncompressedSize = s.ReadInt32();
 						s.ReadBytes(chunkSize - 4);
 						break;
 					case "data":
 						DataSize = s.ReadInt32();
 						RawOutput = s.ReadBytes(DataSize);
 						break;
 					default:
 						var unknownChunkSize = s.ReadInt32();
 						s.ReadBytes(unknownChunkSize);
 						break;
 				}
 			}
 			if (Type == WaveType.ImaAdpcm)
 			{
 				RawOutput = DecodeImaAdpcmData();
 				BitsPerSample = 16;
 			}
 			return true;
 		}
 		public static float WaveLength(Stream s)
 		{
 			s.Position = 12;
 			var fmt = s.ReadASCII(4);
 			if (fmt != "fmt ")
 				return 0;
 			s.Position = 22;
 			var channels = s.ReadInt16();
 			var sampleRate = s.ReadInt32();
 			s.Position = 34;
 			var bitsPerSample = s.ReadInt16();
 			var length = s.Length * 8;
 			return length / (channels * sampleRate * bitsPerSample);
 		}
 		public byte[] DecodeImaAdpcmData()
 		{
 			var s = new MemoryStream(RawOutput);
 			var numBlocks = DataSize / BlockAlign;
 			var blockDataSize = BlockAlign - (Channels * 4);
 			var outputSize = UncompressedSize * Channels * 2;
 			var outOffset = 0;
 			var output = new byte[outputSize];
 			var predictor = new int[Channels];
 			var index = new int[Channels];
 			// Decode each block of IMA ADPCM data in RawOutput
 			for (var block = 0; block < numBlocks; block++)
 			{
 				// Each block starts with a initial state per-channel
 				for (var c = 0; c < Channels; c++)
 				{
 					predictor[c] = s.ReadInt16();
 					index[c] = s.ReadUInt8();
 					/* unknown/reserved */ s.ReadUInt8();
 					// Output first sample from input
 					output[outOffset++] = (byte)predictor[c];
 					output[outOffset++] = (byte)(predictor[c] >> 8);
 					if (outOffset >= outputSize)
 						return output;
 				}
 				// Decode and output remaining data in this block
 				var blockOffset = 0;
 				while (blockOffset < blockDataSize)
 				{
 					for (var c = 0; c < Channels; c++)
 					{
 						// Decode 4 bytes (to 16 bytes of output) per channel
 						var chunk = s.ReadBytes(4);
 						var decoded = ImaAdpcmReader.LoadImaAdpcmSound(chunk, ref index[c], ref predictor[c]);
 						// Interleave output, one sample per channel
 						var outOffsetChannel = outOffset + (2 * c);
 						for (var i = 0; i < decoded.Length; i += 2)
 						{
 							var outOffsetSample = outOffsetChannel + i;
 							if (outOffsetSample >= outputSize)
 								return output;
 							output[outOffsetSample] = decoded[i];
 							output[outOffsetSample + 1] = decoded[i + 1];
 							outOffsetChannel += 2 * (Channels - 1);
 						}
 						blockOffset += 4;
 					}
 					outOffset += 16 * Channels;
 				}
 			}
 			return output;
 		}
 	}
 }
--- a/OpenRA.Mods.Common/OpenRA.Mods.Common.csproj
+++ b/OpenRA.Mods.Common/OpenRA.Mods.Common.csproj
@@ -729,6 +729,7 @@
    <Compile Include="Traits\Render\WithIdleAnimation.cs" />
    <Compile Include="FileFormats\AudReader.cs" />
    <Compile Include="FileFormats\ImaAdpcmReader.cs" />
    <Compile Include="FileFormats\WavReader.cs" />
    <Compile Include="FileFormats\VqaReader.cs" />
    <Compile Include="FileFormats\LCWCompression.cs" />
    <Compile Include="FileFormats\XORDeltaCompression.cs" />